Modular microfluidic system for emulation of human phase I/phase II metabolism.

We present a microfluidic device for coupled phase I/phase II metabolic reactions in vitro. The chip consists of microchannels, which are used as packed bed reactor compartments, filled with superparamagnetic microparticles bearing recombinant microsomal phase I cytochrome P450 or phase II conjugating enzymes (UDP-glucuronosyltransferase). Online coupling of the microfluidic device with LC/MS enabled the quantitative assessment of coupled phase I/phase II transformations, as demonstrated for two different substrates, 7-benzyloxy-4-trifluoromethylcoumarin (BFC) and dextromethorphan (DEX). In contrast, conventional sequential one-pot incubations did not generate measurable amounts of phase II metabolites. Because the microfluidic device is readily assembled from standard parts and can be equipped with a variety of recombinant enzymes, it provides a modular platform to emulate and investigate hepatic metabolism processes, with particular potential for targeted small-scale synthesis and identification of metabolites formed by sequential action of specific enzymes.

Configurable low-cost plotter device for fabrication of multi-color sub-cellular scale microarrays.

The construction and operation of a low-cost plotter for fabrication of microarrays for multiplexed single-cell analyses is reported. The printing head consists of polymeric pyramidal pens mounted on a rotation stage installed on an aluminium frame. This construction enables printing of microarrays onto glass substrates mounted on a tilt stage, controlled by a Lab-View operated user interface. The plotter can be assembled by typical academic workshops from components of less than 15,000 Euro. The functionality of the instrument is demonstrated by printing DNA microarrays on the area of 0.5 cm2 using up to three different oligonucleotides. Typical feature sizes are 5 µm diameter with a pitch of 15 µm, leading to densities of up to 10(4)-10(5) spots/mm2. The fabricated DNA microarrays are used to produce sub-cellular scale arrays of bioactive epidermal growth factor peptides by means of DNA-directed immobilization. The suitability of these biochips for cell biological studies is demonstrated by specific recruitment, concentration, and activation of EGF receptors within the plasma membrane of adherent living cells. This work illustrates that the presented plotter gives access to bio-functionalized arrays usable for fundamental research in cell biology, such as the manipulation of signal pathways in living cells at subcellular resolution.

DNA-modification of eukaryotic cells.

A novel bioorthogonal method for the modification of cells with single-stranded DNA oligomers is compared to five alternative methods with respect to labeling efficacy, specificity, and effects on cell viability. The new method is based on oxime ligation of aminooxybiotin to aldehyde groups installed by periodate cleavage of cell-surface glycans, followed by the coupling of preformed DNA-streptavidin conjugates. As compared with two literature-reported methods based on direct coupling of N-hydroxysuccinimidyl (NHS)-DNA or NHS-biotinylation as well as with techniques based on strain-promoted alkyne-azide cycloaddition, this method shows the highest labeling densities and is sufficiently mild to avoid cell damage. Functionality of the DNA tags is demonstrated by DNA-directed immobilization on solid substrates and assembly of small cell aggregates.

Biochips for cell biology by combined dip-pen nanolithography and DNA-directed protein immobilization.

A general methodology for patterning of multiple protein ligands with lateral dimensions below those of single cells is described. It employs dip pen nanolithography (DPN) patterning of DNA oligonucleotides which are then used as capture strands for DNA-directed immobilization (DDI) of oligonucleotide-tagged proteins. This study reports the development and optimization of PEG-based liquid ink, used as carrier for the immobilization of alkylamino-labeled DNA oligomers on chemically activated glass surfaces. The resulting DNA arrays have typical spot sizes of 4-5 µm with a pitch of 12 µm micrometer. It is demonstrated that the arrays can be further functionalized with covalent DNA-streptavidin (DNA-STV) conjugates bearing ligands recognized by cells. To this end, biotinylated epidermal growth factor (EGF) is coupled to the DNA-STV conjugates, the resulting constructs are hybridized with the DNA arrays and the resulting surfaces used for the culturing of MCF-7 (human breast adenocarcinoma) cells. Owing to the lateral diffusion of transmembrane proteins in the cell's plasma membrane, specific recruitment and concentration of EGF receptor can be induced specifically at the sites where the ligands are bound on the solid substrate. This is a clear demonstration that this method is suitable for precise functional manipulations of subcellular areas within living cells.

Protein-DNA arrays as tools for detection of protein-protein interactions by mass spectrometry.

Analysis of multiple protein-protein interactions using microarray technology remains challenging, and site-specific immobilization of functional proteins is a key step in these approaches. Here we establish the efficient synthesis of protein-DNA conjugates for several members of a small family of GTPases. The family of Rab/Ypt GTPases is intimately involved in vesicular trafficking in yeast and serves as a model for the much larger group of analogous human proteins, the Rab protein family, with more than 60 members. The Ypt-DNA hybrid molecules described here are used for DNA-directed immobilization on glass- and silica-based microarrays. Methods for the detection of protein-DNA conjugates, as well as approaches for nucleotide exchange and distinguishing between GDP- and GTP-bound Ypts on microarrays, are reported. The high specificity of different Rab/Ypt-effector interactions, which also depends on the bound nucleotide, is shown by fluorescence readout of microarrays. Furthermore, initial experiments demonstrate that direct readout by mass spectrometry can be achieved with commercially available instruments. These developments will significantly contribute to the elucidation of complex transport networks in eukaryotic cells.

High-pressure atom transfer radical polymerization of n-butyl acrylate.

High-pressure atom transfer radical polymerization (ATRP) of n-butyl acrylate (BA) is performed in acetonitrile (MeCN) with Cu(I) Br/TPMA [TPMA: tris(2-pyridylmethyl)-amine] as the catalyst up to 5 kbar. Increasing either pressure or temperature significantly enhances the rate of polymerization, while retaining control over the polymerization. The polymerizations under high pressure could be efficiently performed with very low levels of Cu catalyst in the absence of any reducing agents. For example, 100 ppm Cu is sufficient to catalyze the polymerization of BA with targeted degree of polymerization (DPT ) = 1000. The conversion reached 79% in 3.0 h at 80 °C providing PBA with Mn = 112 000, Mw /Mn = 1.12. Since the initial Cu(I) -to-initiator molar ratio is 0.05:1, the molar percentage of terminated chains should remain <5%. For DPT = 10 000 using only 50 ppm Cu catalyst, a polymer with molecular weight Mn = 612 000 (DP = 4800) was obtained at 67% conversion.

Capture and culturing of living cells on microstructured DNA substrates.

A modular system for the DNA-directed immobilization of antibodies was applied to capture living cells on microstructured DNA surfaces. It is demonstrated in two different set-ups, static incubation and hydrodynamic flow, that this approach is well suited for specific capture and selection of cells from culture medium. The adhered cells show intact morphology and they can be cultivated to grow to dense monolayers, restricted to the lateral dimensions of DNA spots on the surface. Owing to the modularity of surface biofunctionalization, the system can readily be configured to serve as a matrix for adhesion and growth of different cells, as demonstrated by specific binding of human embryonic kidney cells (HEK293) and Hodgkin lymphoma L540cy cells onto patches bearing appropriate recognition moieties inside a microfluidic channel. We therefore anticipate that the systems described here should be useful for fundamental research in cell biology or applications in biomedical diagnostics, drug screening, and nanobiotechnology.

User configurable microfluidic device for multiplexed immunoassays based on DNA-directed assembly.

We present a microfluidic device for multiplexed immunoassays based on DNA-directed immobilization. Because of the versatile building blocks used for this technique, it is possible to build up user configurable protein microarrays within the microfluidic system by means of DNA-directed self-assembly, which can be used for immunoassay applications. We demonstrate the performance of our system by parallel detection of cytokines in a multiplex immunoassay, employing silver deposition labeling and optical read-out.

Surface immobilization of biomolecules by click sulfonamide reaction.

Alkyne-modified biomolecules can be immobilized site- and chemoselectively on sulfonylazide slides under very mild conditions by means of the click sulfonamide reaction.

Design and evaluation of single-stranded DNA carrier molecules for DNA-directed assembly.

Due to the exceptional molecular recognition properties of nucleic acids, the computational design of DNA sequence motifs is of paramount interest for a wide variety of applications, ranging from DNA-based nanotechnology and DNA computing to the broad field of DNA microarray technologies. These applications rely on the specificity of Watson-Crick base-pairing, and thus, are highly sensitive to non-specific interactions and the formation of any undesired secondary structures, which contradict an efficient intermolecular hybridization. Here we report on the in silico design and in vitro evaluation of single-stranded DNA (ssDNA) carrier strands for the directional DNA-based positioning of streptavidin (STV) conjugates covalently tagged with short ssDNA oligonucleotides. Each such carrier strand consists of four hybridization sites complementary to the conjugate DNA strands. The high and homogeneous hybridization efficiency measured in vitro by microarray hybridization assays confirms the quality of our in silico sequence design method. Hybridization efficiency of DNA-STV-conjugates depends on the position of the hybridization site in the carrier sequence, where the positions nearest to and farthest from the microarray surface proved to be most favorable.

Synthesis of protein-nucleic acid conjugates by expressed protein ligation.

The synthesis of covalent conjugates of proteins and polyamide nucleic acids (PNA) is accomplished by expressed protein ligation of intein-fusion proteins and a PNA-cysteine conjugate.

A generic building block for C- and N-terminal protein-labeling and protein-immobilization.

Expressed protein ligation (EPL) and bioconjugation based on the maleimide group (MIC-conjugation) provide powerful tools for protein modification. In the light of the importance of site-selectively modified proteins for the study of protein function, a flexible method for the introduction of tags and reporter groups into the C-terminus of proteins employing EPL and MIC-conjugation was developed. We describe the solid-phase synthesis of a generic building block, equipped with fluorescence markers or different functional groups. This generic building block allows for a flexible incorporation of different tags into proteins and was used for the introduction of fluorescence markers into the C-terminus of Rab and Ras GTPases by EPL or MIC-conjugation techniques. In addition, a building block appropriately modified for the incorporation of an azide into proteins was synthesized. Azide-functionalized Ras protein was immobilized on a phosphane-modified surface by means of Staudinger ligation providing a highly chemoselective ligation method for the immobilization of proteins.

Microarray-based in vitro evaluation of DNA oligomer libraries designed in silico.

We report on the microarray-based in vitro evaluation of two libraries of DNA oligonucleotide sequences, designed in silico for applications in supramolecular self-assembly, such as DNA computing and DNA-based nanosciences. In this first study which is devoted to the comparison of sequence motif properties theoretically predicted with their performance in real-life, the DNA-directed immobilization (DDI) of proteins was used as an example of DNA-based self-assembly. Since DDI technologies, DNA computing, and DNA nanoconstruction essentially depend on similar prereguisites, in particular, large and uniform hybridization efficiencies combined with low nonspecific cross-reactivity between individual sequences, we anticipate that the microarray approach demonstrated here will enable rapid evaluation of other DNA sequence libraries.