Site-specific, covalent attachment of poly(dT)-modified peptides to solid surfaces for microarrays

The present study reported proof-of-principle for a kinase assay approach that can detect specific peptide phosphorylation events. The method involves attachment of peptides onto commercial aminosilane and polycarbodiimide-coated glass slides, using a newly developed DNattach linker system that consists of a poly(dT) tail (Nisshinbo Industries Inc.), followed by a detection step using fluorescently labeled antiphosphoamino acid antibodies. The linker-modified peptides are efficiently synthesized by Michael addition between maleimido-modified peptides and thiol-containing DNattach. Specific covalent immobilization of the modified peptides onto aminosilane and poly carbodiimide-coated slides is then achieved by short exposure to UV-light. Highly selective and quantitative recognition by standard antiphosphoamino acid antibodies (antiphosphotyrosine and anti-phosphoGFAP) and kinases (c-Src and PKA) to the corresponding modified peptides on the microarray spots is demonstrated. Furthermore, we found that this immobilization method provides greater signal-to-noise ratio and better discrimination ability of phosphorylated amino acids than does the conventional immobilization technique. The phosphorylation pattern of target sequences, detected using fluorescently labeled antiphosphoamino acid antibodies, revealed that the linker system preference of the kinase is determined by its activity profile.     

Strategies for covalent attachment of DNA to beads

Several covalent attachment chemistries were tested for the immobilization of DNA onto glass beads. The comparison was based on the ability of these chemistries to produce derivatized beads that give good hybridization signals. Cyanuric chloride, isothiocyanate, nitrophenyl chloroformate, and hydrazone chemistries gave us the best (yet comparable) hybridization signals. We further characterized the cyanuric chloride method for the number of attachment sites, number of hybridizable sites, hybridization kinetics, effect of linker length on hybridization intensity and stability of the derivatized beads.     

Cold-plasma modification of oxide surfaces for covalent biomolecule attachment

While many processes have been developed to modify the surface of glass and other oxides for biomolecule attachment, they rely primarily upon wet chemistry and are costly and time-consuming. We describe a process that uses a cold plasma and a subsequent in vacuo vapor-phase reaction to terminate a variety of oxide surfaces with epoxide chemical groups. These epoxide groups can react with amine-containing biomolecules, such as proteins and modified oligonucleotides, to form strong covalent linkages between the biomolecules and the treated surface. The use of a plasma activation step followed by an in vacuo vapor-phase reaction allows for the precise control of surface functional groups, rather than the mixture of functionalities normally produced. By maintaining the samples under vacuum throughout the process, adsorption of contaminants is effectively eliminated. This process modifies a range of different oxide surfaces, is fast, consumes a minimal amount of reagents, and produces attachment densities for bound biomolecules that are comparable to or better than commercially available substrates.     

Direct cloning by covalent attachment of probe DNA to target DNA.

A novel cloning procedure which makes use of covalent attachment of probe DNA to specific target DNA is reported. We show that specific gene fragments found in complex genomes such as the human genome can be cloned directly from a pool of genomic DNA with very high efficiency. This direct cloning method totally eliminates certain steps in current cloning procedures such as construction of DNA libraries and colony (plaque) hybridization. The resulting process has made cloning methods simpler and more time efficient, while achieving high cloning efficiency due to the stable nature of the probe-target DNA complex through covalent bonding. Most importantly, since clones are directly obtained from a pool of genomic DNA, the isolated clones are considered to be faithful copies of the original genes. This has apparently solved the problem of isolating clones with misincorporated bases or chimeric DNA, both of which are often encountered in cloning processes using PCR or other methods involving in vitro DNA synthesis.     

Direct probing: covalent attachment of probe DNA to double-stranded target DNA.

We report a novel procedure, which can be applied to probing of specific DNA, for covalently attaching probe DNA to complementary sequences in double-stranded target DNA. Employing hairpin-like oligonucleotide probes in combination with successive use of recA protein and DNA ligase, probes can be attached directly to target DNA molecules without dissociation of the DNA. The hairpin-like structure of the probes was designed so that the terminus of the probe oligonucleotide can be brought into close stereochemical proximity to the terminus of the complementary strand of target DNA for ligation. Because of the elimination of the DNA dissociation and subsequent hybridization (and washing) steps in the currently employed method, the probing process has become greatly simplified and more efficient and may lead to development of fully automated probing systems.     

Insolubilized coenzymes: the covalent coupling of enzymatically active NAD to glass surfaces

NAD was attached to the surface of glass beads by a diazo coupling procedure. The insolubilized NAD was shown to function as a coenzyme in the yeast alcohol dehydrogenase reaction.     

DNA exhibits multi-stranded binding recognition on glass microarrays

In the course of exploring the hybridization properties of glass DNA microarrays, multi-stranded DNA structures were observed that could not be accounted for by classical Watson-Crick base pairing. Non-denatured double-stranded DNA array elements were shown to hybridize to single-stranded (ss)DNA probes. Similarly, ssDNA array elements were shown to bind duplex DNA probes. This led to a series of experiments demonstrating the formation of multi-stranded DNA structures on the surface of microarrays. These structures were observed with a number of heterogeneous sequences, including both purine and pyrimidine bases, with shared sequence identity between the ssDNA and one of the duplex strands. Furthermore, we observed a strong binding preference near the ends of duplexes containing a 3'-homologous strand. We suggest that such binding interactions on cationic solid surfaces could serve as a model for a number of biological processes mediated through multi-stranded DNA.     

DNA gyrase subunit stoichiometry and the covalent attachment of subunit A to DNA during DNA cleavage.

Escherichia coli DNA gyrase contains a 1:1 ratio of protomers coded by the genes gyrA and gyrB. This along with previous results shows that the enzyme has two copies of each protomer and thus a molecular weight of 400,000. Abortion of the gyrase reaction results in double-strand breakage of the DNA and covalent attachment of both gyrA protomers to the 5'-cut ends. We conclude that the gyrA protomer contains a critical part of the active site for the concerted breakage and reunion reaction of gyrase, the topoisomerase activity of the enzyme.     

Oxime bond formation for the covalent attachment of oligonucleotides on glass support

The chemical attachment of oligonucleotides on glass slides has been achieved using oxime bond formation. This method has been shown very efficient by comparison with the attachment of amino-oligonucleotides via reductive amination.     

Problems and approaches in covalent attachment of peptides and proteins to inorganic surfaces for biosensor applications

Summary Some of the fundamental problems in covalent attachment of peptides and proteins to putative biosensor surfaces are reviewed and specific approaches to these problems discussed. In addition, selected aspects of our recent work utilizing self-assembled monolayer (SAM) systems designed to react selectively with the thiol side chain of Cys in proteins are presented. Uniform attachment of a 21-amino acid peptide antigen through a single Cys residue with retention of biological function (antibody binding) has been attained. Further work with this system may lead to solutions for some of the problems which currently prevent the development of reliable biosensors for industrial and medical use.This paper was presented at a Symposium on Enzyme Electrodes held at the Annual Meeting of the Society of Industrial Microbiology, and the Canadian Society of Microbiologists, in Toronto, Canada (August 3, 1993).     

Enhancing the methyl-donor activity of methylcobalamin by covalent attachment of DNA

The preparation of a covalent DNA conjugate of vitamin B12 by means of heterogeneous solid-phase synthesis is reported. The cyano-corrinoid made available, dipotassium Co(beta)-cyanocobalamin-(3'-->2'),(3'-->5')-bis-2'-deoxythymidyl-3'-ate (K(2)-4), was cleanly methylated at the Co center by electrosynthetic means. Aqueous solutions of the resulting organometallic DNA-B12 conjugate K(2)-5 exhibited spectroscopic properties indicative of significant weakening of the axial (Co-N) bond, together with a 25-times higher basicity relative to Co(beta)-methylcobalamin (2). Methyl-transfer equilibria of pH-neutral aqueous solutions of K(2)-5 and cob(I)alamin (K-7) on one side, and of cob(I)alamin-(3'-->2'),(3'-->5')-bis-2'-deoxythymidyl-3'-ate (K(3)-8) and methylcobalamin (2) on the other, were studied at room temperature (Scheme 3). The NMR-derived data provided an equilibrium constant of ca. 0.3. Activation of K(2)-5 for abstraction of its Co-bound Me group by a nucleophile (such as cob(I)alamin) was, thus, indicated.     

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.     

Microarray fabrication with covalent attachment of DNA using bubble jet technology

We have developed a method for fabricating DNA microarrays that uses a Bubble Jet ink jet device to eject 5'-terminal-thiolated oligonucleotides to a glass surface. The oligonucleotides are covalently attached to the glass surface by heterobifunctional crosslinkers that react with the amino group on the substrate and a thiol group on the oligonucleotide probe. Using this method, we fabricated DNA microarrays that carried 64 groups of 18-mer oligonucleotides encoding all possible three-base mutations in the mutational "hot spot" of the p53 tumor-suppressor gene. These were screened with a fluorescently labeled synthetic 18-mer oligonucleotide derived from the p53 gene, or segments of the p53 gene that had been PCR amplified from genomic DNA of two cell lines of human oral squamous cell carcinoma (SCC). This allowed us to discriminate between matched hybrids and 1 bp-mismatched hybrids.     

The process of epithelial cell attachment to glass surfaces studied by reflexion contrast microscopy

The process of attachment was studied in primary mouse kidney epithelial cell cultures by means of reflexion contrast microscopy, a method developed for studying the cell membrane-substrate relationship. The first in a series of events is simple adherence to the substrate, called close contact. This phenomenon is associated with the greatest extension of lamellar cytoplasm and the fewest number of cell nuclei/unit area. The nuclei of such cells are in close contact with the bottom portion of the cell membrane. Approx. 24 h after planting, as the cultures become more crowded, cells develop a different kind of attachment to the substrate—focal contacts—that are correlated with a decrease in lamellar cytoplasm. Cells detached from the substrate after close contact formation readily reattach, while cells detached after formation of focal contacts do not reattach. After incubation for periods greater than 5 days, the dense cultures degenerate and cells lose their attachment to the glass surface.     

Impact of surface chemistry and blocking strategies on DNA microarrays

The surfaces and immobilization chemistries of DNA microarrays are the foundation for high quality gene expression data. Four surface modification chemistries, poly-L-lysine (PLL), 3-glycidoxypropyltrimethoxysilane (GPS), DAB-AM-poly(propyleminime hexadecaamine) dendrimer (DAB) and 3-aminopropyltrimethoxysilane (APS), were evaluated using cDNA and oligonucleotide sub-arrays. Two un-silanized glass surfaces, RCA-cleaned and immersed in Tris-EDTA buffer were also studied. DNA on amine-modified surfaces was fixed by UV (90 mJ/cm(2)), while DNA on GPS-modified surfaces was immobilized by covalent coupling. Arrays were blocked with either succinic anhydride (SA), bovine serum albumin (BSA) or left unblocked prior to hybridization with labeled PCR product. Quality factors evaluated were surface affinity for cDNA versus oligonucleotides, spot and background intensity, spotting concentration and blocking chemistry. Contact angle measurements and atomic force microscopy were preformed to characterize surface wettability and morphology. The GPS surface exhibited the lowest background intensity regardless of blocking method. Blocking the arrays did not affect raw spot intensity, but affected background intensity on amine surfaces, BSA blocking being the lowest. Oligonucleotides and cDNA on unblocked GPS-modified slides gave the best signal (spot-to-background intensity ratio). Under the conditions evaluated, the unblocked GPS surface along with amine covalent coupling was the most appropriate for both cDNA and oligonucleotide microarrays.     

A fluorescent amino acid probe to monitor efficiency of peptide conjugation to glass surfaces for high density microarrays

Using a fluorescent NBD amino acid, new protease substrates were developed that are attractive because of the excellent chemical stability and long wavelength of excitation (480 nm) of the NBD fluorophore. The fluorescent peptides are synthesized by Fmoc solid-phase peptide synthesis. An example peptide was efficiently immobilized onto a microarray surface using click chemistry, and its proteolysis was monitored by fluorescence imaging. Excellent site specificity was achieved for the protease. Fluorescent peptides are also used to monitor the conjugation efficiency onto a surface using a standard microarray scanner.