Efficient surface patterning of oligonucleotides inside a glass capillary through oxime bond formation

The efficient surface patterning of oligonucleotides was accomplished onto the inner wall of fused-silica capillary tubes as well as on the surface of glass slides through oxime bond formation. The robustness of the method was demonstrated by achieving the surface immobilization of up to three different oligonucleotide sequences inside the same capillary tube. The method involves the preparation of surfaces grafted with reactive aminooxy functionalities masked with the photocleavable protecting group, 2-(2-nitrophenyl) propyloxycarbonyl group (NPPOC). Briefly, NPPOC-aminooxy silane 1 was prepared and used to silanize the glass surfaces. The NPPOC group was cleaved under brief irradiation to unmask the reactive aminooxy group on surfaces. These reactive aminooxy groups were allowed to react with aldehyde-containing oligonucleotides to achieve an efficient surface immobilization. The advantage associated with the present approach is that it combines the high-coupling efficiency of oxime bond formation with the convenience associated with the use of photolabile groups. The present strategy thus offers an alternative approach for the immobilization of biomolecules in the microchannels of "labs on a chip" devices.     

Efficient conjugation of oligonucleotides through aromatic oxime formation

The present work reports on the preparation of oligonucleotide conjugates via the formation of aromatic oxime linkage. The conjugation consists in the reaction between the oligonucleotide derivatized at 5′-extremity with a benzaldehyde moiety and an aminooxy reporter group. The conjugation was found highly efficient and was extended for the conjugation of phosphorothioate oligonucleotide. In addition, the stability of the so-formed oxime conjugate was investigated.     

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.     

Aldehydic oligonucleotide: a key intermediate for the preparation of oligonucleotide conjugates through oxime bond formation

Oligonucleotides functionalized with an aldehyde group are the key intermediates used for the preparation of peptide-oligonucleotide conjugates through the formation of an oxime linkage. Herein, we describe a brief overview of various synthetic protocols developed in our laboratory for the preparation of aldehyde containing oligonucleotides and their subsequent conjugation with peptides.     

Immobilization of oligonucleotides on glass surface using an efficient heterobifunctional reagent through maleimide-thiol combination chemistry

An efficient heterobifunctional reagent, N-(3-triethoxysilylpropyl)-4-(N'-maleimidylmethyl) cyclohexanamide (TPMC), was developed for the immobilization of thiol-modified oligonucleotides on an unmodified glass surface. The heterobifunctionality of the reagent was used for the construction of a DNA microarray in which the triethoxysilyl functionality has specificity toward a glass surface, whereas the maleimide functionality has thiol-modified oligonucleotides via a stable thioether linkage. Immobilization of DNA was achieved by two alternative approaches. In the first approach, the reagent TPMC was treated with oligonucleotides to get triethoxysilyl-oligonucleotide conjugate, which was then covalently attached via specific triethoxysilyl functionality to an unmodified glass surface. In the second approach, the reagent was first covalently linked with an unmodified glass surface to get maleimide functionality on a glass surface, which was then used for the immobilization of oligonucleotides via a stable thioether linkage. The applicability of the reagent was explored by hybridization studies with the fluorescein-labeled complementary DNA strand and in mismatch discrimination.     

Use of carboethoxysulfenyl chloride for disulfide bond formation

The use of carboethoxysulfenyl chloride for disulfide bond formation and concomitant cyclization of five peptides was investigated. Even though cyclic peptides were obtained very rapidly and in good yields when cyclization was performed in aqueous media at different pHs (4 to 7), the final crude peptides were found to contain closely related impurities which, in the case of somatostatin and pressinoic acid, were not generated by air oxidation. This observation may limit the use of carboethoxysulfenyl chloride to those cases where other methods of disulfide bond formation prove inadequate.     

Structural basis for cell surface patterning through NetrinG-NGL interactions

Brain wiring depends on cells making highly localized and selective connections through surface protein-protein interactions, including those between NetrinGs and NetrinG ligands (NGLs). The NetrinGs are members of the structurally uncharacterized netrin family. We present a comprehensive crystallographic analysis comprising NetrinG1-NGL1 and NetrinG2-NGL2 complexes, unliganded NetrinG2 and NGL3. Cognate NetrinG-NGL interactions depend on three specificity-conferring NetrinG loops, clasped tightly by matching NGL surfaces. We engineered these NGL surfaces to implant custom-made affinities for NetrinG1 and NetrinG2. In a cellular patterning assay, we demonstrate that NetrinG-binding selectivity can direct the sorting of a mixed population of NGLs into discrete cell surface subdomains. These results provide a molecular model for selectivity-based patterning in a neuronal recognition system, dysregulation of which is associated with severe neuropsychological disorders.     

Submicron patterning of DNA oligonucleotides on silicon

The covalent attachment of DNA oligonucleotides onto crystalline silicon (100) surfaces, in patterns with submicron features, in a straightforward, two-step process is presented. UV light exposure of a hydrogen-terminated silicon (100) surface coated with alkenes functionalized with N-hydroxysuccinimide ester groups resulted in the covalent attachment of the alkene as a monolayer on the surface. Submicron-scale patterning of surfaces was achieved by illumination with an interference pattern obtained by the transmission of 248 nm excimer laser light through a phase mask. The N-hydroxysuccinimide ester surface acted as a template for the subsequent covalent attachment of aminohexyl-modified DNA oligonucleotides. Oligonucleotide patterns, with feature sizes of 500 nm, were reliably produced over large areas. The patterned surfaces were characterized with atomic force microscopy, scanning electron microscopy, epifluorescence microscopy and ellipsometry. Complementary oligonucleotides were hybridized to the surface-attached oligonucleotides with a density of 7 × 10¹² DNA oligonucleotides per square centimetre. The method will offer much potential for the creation of nano- and micro-scale DNA biosensor devices in silicon.     

The oxime bond formation as an efficient chemical tool for the preparation of 3',5'-bifunctionalised oligodeoxyribonucleotides

The simultaneous conjugation of peptides or carbohydrates at the 3'- and 5'-end of oligodeoxyribonucleotides was achieved very efficiently through chemoselective oxime bond formation. The method employs bifunctionalised oligonucleotides in single step without the need of protection strategy, under mild acidic conditions. The conjugates were obtained in high yields by reacting an oxyamine containing reporter groups (peptide, mono- and disaccharide) with an oligonucleotide carrying an aldehyde at each extremity.     

Glutathionylation of lens proteins through the formation of thioether bond

Formation of lanthionine, a dehydroalanine crosslink, is associated with aging of the human lens and cataractogenesis. In this study we investigated whether modification of lens proteins by glutathione could proceed through an alternative pathway: that is, by the formation of a nonreducible thioether bond between protein and glutathione. Direct ELISA of the reduced water-soluble and water-insoluble lens proteins from human cataractous, aged and bovine lenses showed a concentration-dependent immunoreactivity toward human nonreducible glutathionyl-lens proteins only. The reduced water-insoluble cataractous lens proteins showed the highest immunoreactivity, while bovine lens protein exhibited no reaction. These data were confirmed by dot-blot analysis. The level of this modification ranged from 0.7 to 1.6 nmol/mg protein in water-insoluble proteins from aged and cataractous lenses. N-terminal amino acid determination in the reduced and alkylated lens proteins, performed by derivatization of these preparations with dansyl chloride followed by an exhaustive dialysis, acid hydrolysis and fluorescence detection of dansylated amino acids by RP-HPLC, showed that N-terminal glutamic acid was present in concentration of approximately 0.2 nmol/mg of lens protein. This evidence points out that at least some of the N-terminal amino groups of nonreducible glutathione in the reduced human lens proteins are not involved in a covalent bond formation. Since disulfides were not detected in the reduced and alkylated human lens proteins, GSH is most likely attached to lens proteins through thioether bonds. These results provide, for the first time, evidence that glutathiolation of human lens proteins can occur through the formation of nonreducible thioether bonds.     

Use of a temporary protective group during the synthesis of oligonucleotides with an unnatural bond

Methoxygroup has been used for transient P-protection on H-phosphonate oligonucleotide synthesis. Whereas other H-phosphonate linkages can be irreversibly transformed into phosphoramidates by treatment with alkylamines, the protected phosphoralkoxyl groups generate natural phosphodiester linkages after the final deprotection. The method allows for synthesis of oligonucleotides with addressed position of internucleotide phosphoralkylamidate groups.     

Chemoselective oxime and thiazolidine bond formation: a versatile and efficient route to the preparation of 3'-peptide-oligonucleotide conjugates

Oligonucleotides carrying an aldehyde moiety at the 3'-end were synthesized by the oxidation of a 1,2-diol precursor. These were coupled to peptides bearing a cysteine residue for thiazolidine formation and an aminooxy group for oxime formation. The conjugation reaction proved very efficient and selective, thereby allowing the preparation of 3'-peptide-oligonucleotide conjugates in good yield. The conjugation was achieved in aqueous solution without using any protection strategy. Moreover, the present approach neither requires the use of peptide in excess nor changes the hybridization properties of the conjugates.     

Geminin is required for left-right patterning through regulating Kupffer's vesicle formation and ciliogenesis in zebrafish

Geminin plays an important role in coordinating the cell cycle with anterior–posterior patterning during embryonic development. However, whether it is involved in the regulation of left–right (LR) patterning remains unknown. Here, we reported that geminin is required for setting up heart and visceral laterality during zebrafish development. Defective heart and visceral laterality was observed in geminin morphants. Further study demonstrated that the left-sided nodal/spaw in the lateral plate mesoderm (LPM) as well as the sideness of its downstream targets lefty2 and lefty1 was perturbed in geminin morphants. Upstream of the left-sided Nodal signal along the regulatory cascade of LR asymmetry, knock down of geminin resulted in defective Kupffer’s vesicle (KV) formation and ciliogenesis rather than middle line defects. Predominant distribution of an antisense morpholino against geminin in dorsal forerunner cells (DFCs) led to defective KV morphogenesis and perturbed LR asymmetry, similar to those of geminin morphants, indicating a cell-autonomous role of geminin in regulating KV formation and ciliogenesis. Our results demonstrate that geminin is required for proper KV formation and ciliogenesis, thus playing an important part in setting up LR asymmetry.     

Tissue scaffold surface patterning for clinical applications

Patterned scaffold surfaces provide a platform for highly defined cellular interactions, and have recently taken precedence in tissue engineering. Despite advances in patterning techniques and improved tissue growth, no clinical studies have been conducted for implantation of patterned biomaterials. Four major clinical application fields where patterned materials hold great promise are antimicrobial surfaces, cardiac constructs, neurite outgrowth, and stem cell differentiation. Specific examples include applications of patterned materials to (i) counter infection by antibiotic resistant bacteria, (ii) establish proper alignment and contractile force of regrown cardiac cells for repairing tissue damaged by cardiac infarction, (iii) increase neurite outgrowth for central nervous system wound repair, and (iv) host differentiated stem cells while preventing reversion to a pluripotent state. Moreover, patterned materials offer unique advantages for artificial implants which other constructs cannot. For example, by inducing selective cell adhesion using topographical cues, patterned surfaces present cellular orientation signals that lead to functional tissue architectures. Mechanical stimuli such as modulus, tension, and material roughness are known to influence tissue growth, as are chemical stimuli for cell adhesion. Scaffold surface patterns allow for control of these mechanical and chemical factors. This review identifies research advances in scaffold surface patterning, in light of pressing clinical needs requiring organization of cellular interactions.     

Immobilization of self-quenched DNA hairpin probe with a heterobifunctional reagent on a glass surface for sensitive detection of oligonucleotides

A new sensitive method for the detection of nucleic acids on a glass surface has been described. The self-quenched DNA hairpin probe is immobilized on a glass surface utilizing heterobifunctional reagent, N-(3-triethoxysilylpropyl)-4-(isothiocyanatomethyl)-cyclohexane-1-carboxamide (TPICC). In the closed state fluorescence intensity was quenched due to the presence of guanosine residues in close vicinity of fluorophore while on hybridization with perfectly matched complementary target strand fluorescence was restored. Efficiency and specificity of immobilization as well as thermal stability at variable temperature and pH conditions have been discussed in detail. The method employed has potential for the detection of single nucleotide variations and other diagnostic studies.     

Polyamine-linked oligonucleotides for DNA triple helix formation.

The concept of antigene therapy of disease is based on the ability of an oligonucleotide (the therapeutic agent) to bind to double-stranded genomic DNA (the target associated with the disease). Examples are herein given of the linkage of a series of polyamines to a 21-mer homopyrimidine oligonucleotide. These conjugated 21-mers can each form a triple helix with an appropriate double-stranded homopurine-homopyrimidine DNA according to Hoogsteen base-pairing rules. No triple helix was found when unmodified third strand was used at 10 mM sodium phosphate, pH 6.5, 100 mM sodium chloride solution. In contrast, the spermine-conjugated oligonucleotide had a melting temperature of 42 degrees C. According to the melting profile, the appended spermine moiety was found to affect the Tm only of the triple helix, but not of the subsequent melting of the underlying double helix. The Tm enhancing ability of the spermine-conjugate was found to be better than that of other polyamine-conjugates.     

Design of oligonucleotides for sequence-specific triple-helix formation. Properties of oligonucleotides containing 2'-deoxyxanthosine.

Homopyrimidine-homopurine sequences are targeted by homopyrimidine oligodeoxynucleotides to form triple helix structure. Xanthine was introduced to the third strand of pyrimidine-rich 15-mer oligodeoxy-nucleotides to recognize a cytosine in the purine strand in a homopyrimidine-homopurine duplex target.     

Pathways for protein disulphide bond formation

The folding of many secretory proteins depends upon the formation of disulphide bonds. Recent advances in genetics and cell biology have outlined a core pathway for disulphide bond formation in the endoplasmic reticulum (ER) of eukaryotic cells. In this pathway, oxidizing equivalents flow from the recently identified ER membrane protein Ero1p to secretory proteins via protein disulphide isomerase (PDI). Contrary to prior expectations, oxidation of glutathione in the ER competes with oxidation of protein thiols. Contributions of PDI homologues to the catalysis of oxidative folding will be discussed, as will similarities between eukaryotic and prokaryotic disulphide-bond-forming systems.     

Use of ultrafiltration/diafiltration for the processing of antisense oligonucleotides

Ultrafiltration/diafiltration (UF/DF) has been the hallmark for concentrating and buffer exchange of protein and peptide-based therapeutics for years. Here we examine the capabilities and limitations of UF/DF membranes to process oligonucleotides using antisense oligonucleotides (ASOs) as a model. Using a 3 kDa UF/DF membrane, oligonucleotides as small as 6 kDa are shown to have low sieving coefficients (<0.008) and thus can be concentrated to high concentrations (≤200 mg/mL) with high yield (≥95%) and low viscosity (<15 centipoise), provided the oligonucleotide is designed not to undergo self-hybridization. In general, the oligonucleotide should be at least twice the reported membrane molecular weight cutoff for robust retention. Regarding diafiltration, results show that a small amount of salt is necessary to maintain adequate flux at concentrations exceeding about 40 mg/mL. Removal of salts along with residual solvents and small molecule process-related impurities can be robust provided they are not positively charged as the interaction with the oligonucleotide can prevent passage through the membrane, even for common divalent cations such as calcium or magnesium. Overall, UF/DF is a valuable tool to utilize in oligonucleotide processing, especially as a final drug substance formulation step that enables a liquid active pharmaceutical ingredient.