Automating parallel peptide synthesis for the production of PNA library arrays.

A system was establishedfor the parallel synthesis of peptide library arrays in afully automated manner Synthesis takes place in blocks made of polyoxymethylene that hold during all synthesis steps a polypropylene membrane of 8 x 12 cm. Yields are in the nanomole range, obtained at a low consumption of reagents. The current setup is based on a commercially available pipetting robot and supports the generation of 1536 different oligomers/run. Much higher array densities are possible because the membranes are amicable to spot diameters of down to 200 microm, naturally at a cost of the absolute amount produced of each oligomer The method was put to use for the creation of arrayed libraries of peptide nucleic acids (PNAs). These can be employed both as a source of PNA molecules applied individually in experimentation subsequent to their release or as intact oligomer arrays in hybridization analyses.     

Light directed massively parallel on-chip synthesis of peptide arrays with t-Boc chemistry

Peptide and peptidomimetic molecule arrays are emerging powerful tools for parallel screening of binding in proteomics and pharmaceutical discovery research. Up to now the common method of preparing peptide arrays was based on spotting on glass using a library of presynthesized peptides. However, due to the large number of monomers (amino acids) it is not possible to have combinatorial libraries which include all combinations of natural and synthetic amino acids. We describe a very flexible on-chip oligopeptide synthesis method which uses the well developed t-Boc based solid state synthesis chemistry. A very high degree of flexibility is achieved by using light photo generated acids and maskless projection lithography for spatially directed deprotection. Use of microfluidic chips enables moderately high densities, short reaction times and off-the-shelf chemicals. Examples are given from synthesis of metal ion binding peptides and epitope binding assays.     

In situ control of cell adhesion using photoresponsive culture surface

A photoresponsive culture surface (PRCS) allowing photocontrol of cell adhesion was prepared with a novel polymer material composed of poly(N-isopropylacrylamide) having spiropyran chromophores as side chains. Cell adhesion of the surface was drastically enhanced by the irradiation with ultraviolet (UV) light (wavelength: 365 nm); after subsequent cooling and washing on ice, many cells remained in the irradiated region, whereas most cells were removed from the nonirradiated region. The cell adhesion of the PRCS, which had been enhanced by previous UV irradiation, was reset by the visible light irradiation (wavelength 400-440 nm) and the annealing at 37 degrees C for 2 h. Also it was confirmed that the regional control of cell adhesion was induced several times by repeating the same series of operations. Further, living cell patterning with the 200 microm line width was produced readily by projecting UV light along a micropattern on the PRCS on which the living cells had been seeded uniformly in advance. By using a fluorescent probe that stains living cells only, it was confirmed that the cells maintained sufficient viability even after UV light irradiation followed by cooling and washing.     

In situ synthesis of protein arrays

In situ or on-chip protein array methods use cell free expression systems to produce proteins directly onto an immobilising surface from co-distributed or pre-arrayed DNA or RNA, enabling protein arrays to be created on demand. These methods address three issues in protein array technology: (i) efficient protein expression and availability, (ii) functional protein immobilisation and purification in a single step and (iii) protein on-chip stability over time. By simultaneously expressing and immobilising many proteins in parallel on the chip surface, the laborious and often costly processes of DNA cloning, expression and separate protein purification are avoided. Recently employed methods reviewed are PISA (protein in situ array) and NAPPA (nucleic acid programmable protein array) from DNA and puromycin-mediated immobilisation from mRNA.     

Continuous perfusion microfluidic cell culture array for high-throughput cell-based assays

We present for the first time a microfluidic cell culture array for long-term cellular monitoring. The 10 x 10 array could potentially assay 100 different cell-based experiments in parallel. The device was designed to integrate the processes used in typical cell culture experiments on a single self-contained microfluidic system. Major functions include repeated cell growth/passage cycles, reagent introduction, and real-time optical analysis. The single unit of the array consists of a circular microfluidic chamber, multiple narrow perfusion channels surrounding the main chamber, and four ports for fluidic access. Human carcinoma (HeLa) cells were cultured inside the device with continuous perfusion of medium at 37 degrees C. The observed doubling time was 1.4 +/- 0.1 days with a peak cell density of approximately 2.5*10(5) cells/cm(2). Cell assay was demonstrated by monitoring the fluorescence localization of calcein AM from 1 min to 10 days after reagent introduction. Confluent cell cultures were passaged within the microfluidic chambers using trypsin and successfully regrown, suggesting a stable culture environment suitable for continuous operation. The cell culture array could offer a platform for a wide range of assays with applications in drug screening, bioinformatics, and quantitative cell biology.     

PEGA supports for combinatorial peptide synthesis and solid-phase enzymatic library assays

Permeable resins cross-linked with long PEG chains were synthesized for use in solid-phase enzyme library assays. High molecular weight bis-amino-polyethylene glycol (PEG) 4000, 6000, 8000 were synthesized by a three-step reaction starting from PEG-bis-OH. Macromonomers were synthesized by partial or di-acryloylation of bis-amino-PEG derivatives. Bis/mono-acrylamido–PEG were copolymerized along with acrylamide by inverse suspension copolymerization to yield a less cross-linked resin (Type I, compounds 6–9 ). Furthermore, acryloyl–sarcosin ethyl ester was co-polymerized along with bis-acrylamido PEG to obtain more crosslinked capacity resin (Type II, compounds 13–19 ). N,N-Dimethylacrylamide was used as a co-monomer in some cases. The polymer was usually obtained in a well-defined beaded form and was easy to handle under both wet and dry conditions. The supports showed good mechanical properties and were characterized by studying the swelling properties, size distribution of beads, and by estimating the amino group capacity. Depending on the PEG chain length, the monomer composition and the degree of cross-linking the PEGA supports showed a high degree of swelling in a broad range of solvents, including water, dichloromethane, DMF, acetonitril, THF and toluene; no swelling was observed in diethyl ether. The PEGA resins (Type I ) with an amino acid group capacity between 0.07 and 1.0 mmol/g could be obtained by variation of the monomer composition in the polymerization mixture. Fluorescent quenched peptide libraries were synthesized on the new polymer using a multiple column library synthesizer and incubated with the matrix metalloproteinase MMP-9 after it had been activated by 4-aminophenyl mercuric acetate resulting in 67/83 kDa active enzyme. The bright beads were separated manually under a fluorescence microscope and sequenced to obtain peptide substrates for MMP-9. After treatment with ethylene diamine, high-loaded resins (Type II ) have been employed in continuous flow peptide synthesis to yield peptides in excellent yield and purity. © 1998 European Peptide Society and John Wiley & Sons, Ltd.     

Effects on interfacial properties and cell adhesion of surface modification by pectic hairy regions

Polystyrene Petri dishes, aminated by a plasma deposition process, were surface modified by the covalent linking of two different enzymatically modified hairy regions (HRs) from pectin containing, for example, rhamnogalacturonan-I and xylogalacturonan structural elements. The two polysaccharide preparations share the same structural elements of apple pectin, but the relative amounts and lengths of the neutral side chains present differ. Surface analysis by X-ray photoelectron spectroscopy, contact angle measurement, and atomic force microscope (AFM) force-separation curves was used to characterize the effects on surface chemistry and interfacial forces of the surface modification process. Cell adhesion experiments using continuous L-929 fibroblasts and primary aortic smooth muscle cells were performed to evaluate the effect of the polysaccharide nature on cell adhesion. Results show that immobilization of the HR affects the interfacial field of forces and the cell behavior: "equilibrium" contact angles, obtained by a recently introduced vibrational approach, decrease after HR immobilization reaching a value close to 20 degrees . AFM force-separation curves show a more extended (or softer) interface in the case of the HR bearing longer side chains. Accordingly, depending on the HR preparation, cells shifted from spread morphology and adhesion behavior quantitatively comparable to that observed on conventional tissue culture polystyrene to rounded morphology and significantly lower adhesion. These data show that engineering of plant pectins can be a valuable tool to prepare novel and finely tuned polysaccharides having different chemico-physical and biological properties, to be used in the surface modification of medical devices and materials.     

Application of disposable plastic microfluidic device arrays with customized chemistries to multiplexed biochemical assays

Plastic microfluidic array platforms and synergistic multiplexed assay chemistries are under development for a variety of applications, including assays of gene expression, proteomics, genotyping, DNA sequencing and fragment analysis, sample preparation and high-throughput pharmaceutical discovery. The low production costs of plastic substrates makes possible economical single-use device arrays, eliminating cleaning and sample-to-sample carryover contamination. Hundreds of microchannels and reservoirs are readily included on a single microtitre-plate-size substrate, enabling the manufacture of highly parallel fluidic array systems to increase throughput and speed.     

High-throughput analysis of single hematopoietic stem cell proliferation in microfluidic cell culture arrays

Heterogeneity in cell populations poses a major obstacle to understanding complex biological processes. Here we present a microfluidic platform containing thousands of nanoliter-scale chambers suitable for live-cell imaging studies of clonal cultures of nonadherent cells with precise control of the conditions, capabilities for in situ immunostaining and recovery of viable cells. We show that this platform mimics conventional cultures in reproducing the responses of various types of primitive mouse hematopoietic cells with retention of their functional properties, as demonstrated by subsequent in vitro and in vivo (transplantation) assays of recovered cells. The automated medium exchange of this system made it possible to define when Steel factor stimulation is first required by adult hematopoietic stem cells in vitro as the point of exit from quiescence. This technology will offer many new avenues to interrogate otherwise inaccessible mechanisms governing mammalian cell growth and fate decisions.     

Improving fluorescence-based assays for the in vitro analysis of cell adhesion and migration

Cell adhesion and cell migration are two primary cellular phenomena to be approached in vitro in order to allow for the effective dissection of the individual events and the unravelling of their underlying molecular mechanisms. The use of assays dedicated to the analysis of cell adhesion and migration in vitro also affords an efficient way of conducting larger basic and applied research screenings of the conditions affecting these processes and are potentially exploitable in the context of routine tests in the biological and medical fields. Therefore, there is a substantial interest in devicing more rationale such assays and major contributions in this direction have been provided by the advent of procedures based on fluorescent cell tagging. In this article we describe three fluorescence-based model assays for the qualitative and quantitative assessment of cell adhesion and cell locomotion in static and dynamic conditions. The assays are easily performed, accurate and reproducible, and can be automatized for high-throughput screenings of cell behavior in vitro. Performance of the assays involves the use of certain dedicated disposable accessories, which are commercially available, and a few instruments that, due to their versatility, can be regarded as constituents of a more generic laboratory setup.     

Flagellar adhesion in chlamydomonas induces synthesis of two high molecular weight cell surface proteins

Because our previous studies (Snell, W.J., and W.S. Moore, 1980, J. Cell Biol. 84:203- 210) on the mating reaction of chlamydomonas reinhardtii showed that there was an adhesion-induced turnover of proteins whose synthesis is induced during aggregation. Analysis by SDS PAGE and autoradiography showed that proteins of 220,000 M(r) and 165, 000 M(r) (designated A(1) and A(2) respectively) consistently showed a high rate of synthesis only in flagella or flagellar membrane-enriched fractions prepared from aggregating gametes. Since the two proteins were soluble in the non-ionic detergent NP-40 and were removed from intact cells by a brief pronase treatment, it is likely that A(1) and A(2) are membrane proteins expose on the cell surface. A(1) and A(2) were each synthesized by gametes of both mating types (mt(-) and mt(+)) and synthesis of these two proteins could be detected in the normal mating reaction (wild type mt(-) and mt(+)), in mixtures of mt(-) and impotent mt(+) gametes (which could aggregate but not fuse), and in mixtures of gametes of a single mating type with isolated flagella of the opposite mating type. Cells aggregating in tunicamycin, an inhibitor of protein glycosylation, lost their adhesiveness during aggregation and did not synthesize the 220,000 M(r) protein but instead produced a protein (possibly an underglycosylated form of A(1)) of slightly lower mol wt. The 220,000 and 165,000 M(R) proteins appeared to be flagellar proteins and not cell wall proteins because A(1) and A(2) did not co-migrate with previously identified cell wall proteins, and synthesis of the two proteins could not be detected in flagella-less (bald-2) mutant cells. Analysis of the adhesive activity of sucrose gradient fraction of detergent (octyl glucoside)-solubilized flagellar membranes revealed that fractions containing A(1) and A(2) did not have detectable adhesive activity. The possibility remains that A(1) and A(2) are adhesion molecules whose activity could not be measured in the assay we used. Alternatively, the 220,000 and 165,000 M(r) proteins may be inactivated adhesion molecules or else they may be flagellar surface proteins involved only indirectly in the adhesion process.     

Peptide and small molecule microarray for high throughput cell adhesion and functional assays

A novel class of chemical microchips consisting of glass microscope slides was prepared for the covalent attachment of small molecule ligands and peptides through site-specific oxime bond or thiazolidine ring ligation reaction. Commercially available microscope slides were thoroughly cleaned and derivatized with (3-aminopropyl)triethoxysilane (APTES). The amino slides were then converted to glyoxylyl derivatives via two different routes: (1) coupling of Fmoc-Ser followed by deprotection and oxidation, or (2) coupling with protected glyoxylic acid and final deprotection with HCl. Biotin or peptide ligands derivatized at the carboxyl terminus with a 4,7,10-trioxa-1,13-tridecanediamine succinimic acid linker and an amino-oxy group or a 1,2-amino-thiol group (e.g., cysteine with a free N(alpha)-amino group) were printed onto these slides using a DNA microarray spotter. After chemical ligation, the microarray of immobilized ligands was analyzed with three different biological assays: (1) protein-binding assay with fluorescence detection, (2) functional phosphorylation assay using [gamma(33)P]-ATP and specific protein kinase to label peptide substrate spots, and (3) adhesion assay with intact cells. In the cell adhesion assay, not only can we determine the binding specificity of the peptide against different cell lines, we can also determine functional cell signaling of attached cells using immunofluorescence techniques in situ on the microchip. This chemical microchip system enables us to rapidly analyze the functional properties of numerous ligands that we have identified from the "one-bead one-compound" combinatorial library method.     

Conflicting roles for a cell surface modification in Salmonella

Chemical modifications of components of the bacterial cell envelope can enhance resistance to antimicrobial agents. Why then are such modifications produced only under specific conditions? Here, we address this question by examining the role of regulated variations in O‐antigen length in the lipopolysaccharide (LPS), a glycolipid that forms most of the outer leaflet of the outer membrane in Gram‐negative bacteria. We determined that activation of the PmrA/PmrB two‐component system, which is the major regulator of LPS alterations in Salmonella enterica serovar Typhimurium, impaired growth of Salmonella in bile. This growth defect required the PmrA‐activated gene wzz_st, which encodes the protein that determines long O‐antigen chain length and confers resistance to complement‐mediated killing. By contrast, this growth defect did not require the wzz_fepE gene, which controls production of very long O‐antigen, or other PmrA‐activated genes that mediate modifications of lipid A or core regions of the LPS. Additionally, we establish that long O‐antigen inhibits growth in bile only in the presence of enterobacterial common antigen, an outer‐membrane glycolipid that contributes to bile resistance. Our results suggest that Salmonella regulates the proportion of long O‐antigen in its LPS to respond to the different conditions it faces during infection.     

Sensitivity of ex situ and in situ spectral surface plasmon resonance sensors in the analysis of protein arrays

We have investigated the sensitivity of ex situ (analysis under air condition) and in situ (analysis under liquid condition) spectral SPR sensors, which were self-constructed with fiber optic spectrometers. The sensitivity of SPR sensors was analyzed in the wavelength range of 550-780 nm by the interactions of streptavidin and biotinylated IgG, and the sensitivity was dependent on the wavelength of measurements. The sensitivity of an ex situ SPR sensor operated at the long wavelength range from 712 nm was approximately 2.6 times higher than that at the short wavelength range from 571 nm. In addition, the sensitivity of an ex situ spectral SPR sensor was about twice as high as that of an in situ spectral SPR sensor for the same resonance wavelength range. This was interpreted in that the difference in sensitivity between two SPR sensors was significantly caused by the evanescent field intensity at the metal/dielectric interface. Thus, it was suggested that ex situ spectral SPR sensors operated at the long wavelength range are sensitive biosensors for the high-throughput analysis of protein interactions on protein arrays.     

The synergy peptide PHSRN and the adhesion peptide RGD mediate cell adhesion through a common mechanism

This work reports on the role of the synergy peptide PHSRN in mediating the adhesion of cells. The attachment of baby hamster kidney cells and 3T3 Swiss fibroblasts to model substrates presenting either GRGDS or PHSRN was evaluated using self-assembled monolayers of alkanethiolates on gold presenting the peptide ligands mixed with tri(ethylene glycol) groups. These substrates permit rigorous control over the structures and densities of peptide ligands and at the same time prevent nonspecific interactions with adherent cells. Both cell types attached efficiently to monolayers presenting either the RGD or the PHSRN peptide but not to monolayers presenting scrambled peptide GRDGS or HRPSN. Cell attachment was comparable on substrates presenting either peptide ligand but less efficient than on substrates presenting the protein fibronectin. The degree of cell spreading, however, was substantially higher on substrates presenting RGD relative to PHSRN. Staining of 3T3 fibroblasts with anti-vinculin and phalloidin revealed clear cytoskeletal filaments and focal adhesions for cells attached by way of either RGD or PHSRN. Inhibition experiments showed that the attachment of 3T3 fibroblasts to monolayers presenting RGD could be inhibited completely by a soluble RGD peptide and partially by a soluble PHSRN peptide. IMR 90 fibroblast attachment to monolayers presenting PHSRN could be inhibited with anti-integrin alpha(5) or anti-integrin beta(1) antibody. This work demonstrates unambiguously that PHSRN alone can support the attachment of cells and that the RGD and PHSRN bind competitively to the integrin receptors.     

A modification of isocitrate and malate dehydrogenase assays for use in crude cell free extracts

A modification of the assays for isocitrate and malate dehydrogenase, using phenazine methosulphate and 2,6-dichlorophenolindophenol, permits measurements on cell-free extracts. Phenazine methosulfate at concentrations higher than 30 nmoles/3 ml prevents the accumulation of NADPH or NADH and thus reduces errors due to endogenous oxidation of these compounds. The use of 2,6-dichlorophenolindophenol rather than a tetrazolium salt as the terminal electron acceptor allows continuous spectrophotometric measurement of enzyme activities.Assay for NADP-specific isocitrate dehydrogenase can be performed in aerobic or anaerobic conditions. Assays for malate dehydrogenase should be run under anaerobic conditions because of the interference by oxygen on the phenazine methosulfate mediated reduction of 2,6-dichlorophenolindophenol by NADH. Under anaerobic conditions, where NADH oxidase is inoperative, the phenazine methosulfate/dichlorophenolindophenol assay is more sensitive than the assay using direct measurement of NADH at 340 nm.     

Dynamic monitoring of cell adhesion and spreading on microelectronic sensor arrays

Cellular interaction with and adhesion on different biological surfaces is a dynamic and integrated process requiring the participation of specialized cell surface receptors, structural proteins, signaling proteins, and the cellular cytoskeleton. In this report, the authors describe a label-free and real-time method for measuring and monitoring cell adhesion on special microplates integrated with electronic cell sensor arrays. These plates were used in conjunction with the real-time cell electronic sensing (RT-CES) system to dynamically and quantitatively monitor the specific interaction of fibroblasts with extracellular matrix (ECM) proteins and compared with standard adhesion techniques. Cell adhesion on ECM-coated cell sensor arrays is dependent on the concentration of ECM proteins coated and is inhibited by agents that disrupt the interaction of ECM with cell surface receptors. Furthermore, the authors demonstrate that the integrity of the actin cytoskeleton is required for productive cell adhesion and spreading on ECM-coated microelectronic sensors. Confirming earlier results, it is shown that interfering with Src expression or activity, via siRNA or small molecule, results in the disruption of adhesion and spreading of Bx PC3 cells. The results indicate that the RT-CES system offers a convenient and quantitative means of assessing the kinetics of cell adhesion in a high-throughput manner.     

Evaluation of a sensitive detection method for peptide arrays prepared by SPOT synthesis

The growing range of applications for peptide arrays prepared by SPOT synthesis confirms that they are a powerful proteomics technique to study numerous aspects of molecular interaction events. The most frequent application for peptide arrays prepared by SPOT synthesis is the identification of linear epitopes that are recognized by antibodies. In the conventional format using secondary antibodies for detection unspecific binding and high background have been observed. This leads to difficulties in evaluation of developed membranes. Especially for application with combinatorial libraries false positive results are to be avoided. To circumvent this issue, we directly labeled compounds of interest with biotin and detected binding by incubation with streptavidin-horseradish peroxidase via chemiluminescence. Optimization of method conditions led to a very sensitive detection technique with no or low number of unspecific spots, which is superior to conventional detection with secondary antibodies. As one consequence, evaluation of competitive assays got more reliable.     

DNA modification of live cell surface

We report a novel approach for the attachment of DNA fragments to the surface of live cells. By using fluorescence microscopy and flow cytometry we demonstrated that our synthetic conjugates of fatty acid with oligonucleotides can be incorporated in plasma membrane and then hybridized with complementary sequences at the cell surface. Method permits to control amount of immobilized DNA on the cell surface. All procedures can be completed within minutes and do not alter cell viability. Using this approach we tethered floating myeloid HL-60 cells to adherent A431 epitheliocytes in a sequence specific fashion. Thus, this method allows rapid and simple DNA multicoding of the cell surface and, therefore, opens new opportunities in manipulating with cell–cell interactions.     

Cell surface carbohydrates in cell adhesion.

Carbohydrates are ubiquitous constituents of cell surfaces, and possess many characteristics that make them ideal candidates for recognition molecules. In many systems where cell adhesion plays a critical role, carbohydrate binding proteins have been shown to bind to cell surface carbohydrates and participate in cell-cell interactions. Such systems include fertilization, development, pathogen-host recognition and inflammation. In particular the recent discovery of the LEC-CAMs and their importance in leukocyte biology has refocused attention on lectin-mediated cell adhesion. The LEC-CAMs offer good targets for the development of therapeutics based on carbohydrate structures.