Recent advances in cell micropatterning techniques for bioanalytical and biomedical sciences

Cell micropatterning is an important technique for a wide range of applications, such as tissue engineering, cell-based drug screening, and fundamental cell biology studies. This paper overviews cell patterning techniques based on chemically modified substrates with different degrees of cell adhesiveness. In particular, the focus is on dynamic substrates that change their cell adhesiveness in response to external stimuli, such as heat, voltage, and light. Such substrates allow researchers to achieve an in situ alteration of patterns of cell adhesiveness, which is useful for co-culturing multiple cell types and analyzing dynamic cellular activities. As an example of dynamic substrates, we introduce a dynamic substrate based on a caged compound, where we accomplished a light-driven alteration of cell adhesiveness and the analysis of a single cell's motility.     

Quantitative SERS sensors for environmental analysis of naphthalene

In the investigation of chemical pollutants, such as PAHs (Polycyclic Aromatic Hydrocarbons) at low concentration in aqueous medium, Surface-Enhanced Raman Scattering (SERS) stands for an alternative to the inherent low cross-section of normal Raman scattering. Indeed, SERS is a very sensitive spectroscopic technique due to the excitation of the surface plasmon modes of the nanostructured metallic film. The surface of quartz substrates was coated with a hydrophobic film obtained by silanization and subsequently reacted with polystyrene (PS) beads coated with gold nanoparticles. The hydrophobic surface of the SERS substrates pre-concentrates non-polar molecules such as naphthalene. Under laser excitation, the SERS-active substrates allow the detection and the identification of the target molecules localized close to the gold nanoparticles. The morphology of the SERS substrates based on polystyrene beads surrounded by gold nanoparticles was characterized by scanning electron microscopy (SEM). Furthermore, the Raman fingerprint of the polystyrene stands for an internal spectral reference. To this extent, an innovative method to detect and to quantify organic molecules, as naphthalene in the range of 1 to 20 ppm, in aqueous media was carried out. Such SERS-active substrates tend towards an application as quantitative SERS sensors for the environmental analysis of naphthalene.     

Characterization of new fluorescent peroxidase substrates

The reagents Lumigen PS-1 and Lumigen PS-3 were originally developed as chemiluminescent substrates for ultrasensitive detection of horseradish peroxidase (HRP) in homogeneous solution and membrane blotting assays. However, an additional unique feature of these acridan-based reagents is the generation of a fluorescent species on reaction with peroxidase, a property which has been termed as chemifluorescence. These reagents, therefore, represent the first dual-use substrates enabling both chemiluminescent and fluorescent detection. We have developed several additional acridan-based substrates for fluorescent detection of HRP which are capable of subattomole detection sensitivity. By varying several structural parameters within the class of compounds we have produced substrates which either produce fluorescence alone or both chemiluminescence and fluorescence.     

Microstructure and electrical properties of BaTiO<Subscript>3</Subscript> and (Ba,Sr)TiO<Subscript>3</Subscript> ferroelectric thin films on nickel electrodes

Nickel thin films have been sputtered on standard Si/SiO₂ substrates with TiO₂ as an adhesive layer. The thermal stability of these substrates was analyzed. SEM images show an increase in grain size with annealing temperature. They were found to be stable till 800°C, beyond which the nickel layer disintegrated. These substrates were used for deposition of BaTiO₃ and (Ba,Sr)TiO₃ dielectric thin films under a reducing atmosphere. The dielectric thin films were processed with various pyrolysis and annealing temperatures in order to optimize the dielectric properties. Increased pyrolysis temperatures showed an increase in the grain size. Results on these nickelised substrates were finally compared with dielectric films deposited on platinized silicon substrates under identical conditions but crystallized in an oxygen atmosphere.     

A chemical reporter for protein AMPylation

Protein AMPylation is an emerging post-translational modification, which plays key roles in bacterial pathogenesis and cell biology. Enzymes with AMPylation activity, referred to as AMPylators, have been identified in several bacterial pathogens and eukaryotes. To facilitate the study of this unique modification, we developed an alkynyl chemical reporter for detection and identification of protein AMPylation substrates. Covalent functionalization of AMPylation substrates with the alkynyl reporter in lieu of adenylyl 5'-monophosphate (AMP) allows their subsequent bioorthogonal ligation with azide-fluorescent dyes or affinity enrichment tags. We show that this chemical reporter is transferred by a range of AMPylators onto their cognate protein substrates and allows rapid detection and identification of AMPylated substrates.     

Low background FRET-substrates for lipases and esterases suitable for high-throughput screening under basic (pH 11) conditions

FRET-based fluorogenic substrates for lipases and esterases were prepared in four steps from commercially available building blocks. The substrates are pyrenebutyric acid monoesters of aliphatic 1,2-diols bearing a dinitrophenylamino group as a quencher. The most enzyme-reactive substrate is ester 2a. The substrates do not show any measurable background reaction in the absence of enzyme even at pH 11, but react fast and specifically with lipases and esterases. These substrates offer an unprecedented and practical solution to the long-standing problem of a simple yet efficient high-throughput screening tool for lipase activities under basic conditions.     

Site‐Specific N‐Terminal Labeling of Peptides and Proteins using Butelase 1 and Thiodepsipeptide

An efficient ligase with exquisite site‐specificity is highly desirable for protein modification. Recently, we discovered the fastest known ligase called butelase 1 from Clitoria ternatea for intramolecular cyclization. For intermolecular ligation, butelase 1 requires an excess amount of a substrate to suppress the reverse reaction, a feature similar to other ligases. Herein, we describe the use of thiodepsipeptide substrates with a thiol as a leaving group and an unacceptable nucleophile to render the butelase‐mediated ligation reactions irreversible and in high yields. Butelase 1 also accepted depsipeptides as substrates, but unlike a thiodesipeptide, the desipeptide ligation was partially reversible as butelase 1 can tolerate an alcohol group as a poor nucleophile. The thiodesipeptide method was successfully applied in N‐terminal labeling of ubiquitin and green fluorescent protein using substrates with or without a biotin group in high yields.     

Generation of Carbenes by Photochemical Cycloelimination

A wide variety of shelf stable substrates undergo photochemical cycloelimination under relatively mild conditions. Suitable substrates include cyclopropanes, oxiranes, aziridines, and diazirines, as well as 3 H-pyrazoles and 1,3-dioxolanes. Carbenes prepared from these substrates as well as certain cyclic carbonates, sulfites, and phosphoranes behave chemically in a manner similar to divalent carbon species produced from conventional diazo precursors, namely, they react with alkenes to give cyclopropanes and undergo insertion into C? H bonds of alkanes. In many cases the carbenes formed may also be detected by EPR and optical spectroscopic methods.     

PNA-encoded protease substrate microarrays

Our current understanding of the role and regulation of protease activity in normal and pathogenic processes is limited by our ability to measure and deconvolute their enzymatic activity. To address this limitation, an approach was developed that utilizes rhodamine-based fluorogenic substrates encoded with PNA tags. The PNA tags address each of the substrates to a predefined location on an oligonucleotide microarray through hybridization, thus allowing the deconvolution of multiple signals from a solution. A library of 192 protease substrates was prepared by split and mix combinatorial synthesis. The methodology and validation of this approach for profiling proteolytic activity from single proteases and from those in crude cell lysates as well as clinical blood samples is described.     

Selection of new chromogenic substrates of serine proteinases using combinatorial chemistry methods

Chemical synthesis, physicochemical characterization and kinetic investigations of a tetrapeptide library of chromogenic substrates containing the amide of 5-amino-2-nitrobenzoic acid (Anb(5,2)-NH(2)) at their C-termini are reported. Anb(5,2)-NH(2) served as a chromophore released upon enzymatic action. The library consisting of 9567 peptides was synthesized using the portioning-mixing method and was screened against bovine a-chymotrypsin and human leukocyte elastase in solution applying an iterative approach. The selected chromogenic substrates were resynthesized and further modified at their N- and C-termini. Finally, two sequences, Z-Phe-Ala-Thr-Tyr-Anb(5,2)-NH(2) and Z-Phe-Phe-Pro-Val-Anb(5,2)-NH(2), were obtained as highly specific substrates for bovine alpha-chymotrypsin and human leukocyte elastase, respectively. The method of synthesis and selection of chromogenic substrates of serine proteinases described herein is straightforward and can be applied to design substrates for other proteases.     

A rapid modified gas chromatographic assay for esterase activity.

A rapid modified procedure for the gas chromatogrpahic determination of esterase activity was studied. Aliphatic esters such as ethyl n-butyrate, n-propul n-butyrate, n-butyl n-butyrate and n-amyl n-butyrate were used as substrates and acetone was chosen as the most suitable solvent for dissolving the substrates in order to avoid alcoholysis. The enzyme reaction was started in a mixture of 0.03 M phosphate buffer, pH 7.90, containing an adequals, an aliquot of the reaction solutionwas injected directly on to a gas chromatograph and the alcohols produced were separated.     

Enzymatic formation of unnatural novel polyketides from alternate starter and nonphysiological extension substrate by chalcone synthase

[reaction: see text] In the chalcone synthase (CHS) enzyme reaction, both the starter molecule and the extension unit of the polyketide chain elongation reaction were simultaneously replaced with nonphysiological substrates. When incubated with benzoyl-CoA and methylmalonyl-CoA as substrates, recombinant CHS from Scutellaria baicalensis afforded an unnatural novel triketide, 4-hydroxy-3,5-dimethyl-6-phenyl-pyran-2-one, along with a tetraketide, 4-hydroxy-3,5-dimethyl-6-(1-methyl-2-oxo-2-phenyl-ethyl)-pyran-2-one. On the other hand, the enzyme also accepted hexanoyl-CoA and methylmalonyl-CoA as substrates to produce an unnatural novel triketide, 4-hydroxy-3,5-dimethyl-6-pentyl-pyran-2-one.     

Development of protein, peptide, and small molecule catalysts using catalysis-based selection strategies

We have developed peptide catalysts and antibody catalysts that catalyze aldol, retro-aldol, and Michael reactions via an enamine mechanism using reaction-based selections with 1,3-diketone derivatives. Nucleophilic amino groups of the catalysts were covalently trapped during the selections. We have also developed fluorogenic substrates that are useful for real-time monitoring of the progress of bond-forming reactions, such as aldol reactions, by an increase in fluorescence. These fluorogenic substrates have been used to monitor peptide-catalyzed, antibody-catalyzed, enzyme-catalyzed, and small molecule-catalyzed reactions. Catalysis-based screening using fluorogenic substrates will accelerate rapid identification of superior catalysts and reaction conditions.     

丁基锂与氯化铜存在条件下仲胺偶联形成N-N键的新方法

报道了以仲胺反应底物经丁基锂夺去活性质子,无水氯化铜氧化偶联形成N—N键的新方法.共完成了11种底物尝试,所得产物肼的产率在17％～76％之间.相关合成方法是一种从仲胺制备对称取代肼的高效合成方法.     

Probing Selectivity and Creating Structural Diversity Through Hybrid Polyketide Synthases

Engineering polyketide synthases (PKS) to produce new metabolites requires an understanding of catalytic points of failure during substrate processing. Growing evidence indicates the thioesterase (TE) domain as a significant bottleneck within engineered PKS systems. We created a series of hybrid PKS modules bearing exchanged TE domains from heterologous pathways and challenged them with both native and non‐native polyketide substrates. Reactions pairing wildtype PKS modules with non‐native substrates primarily resulted in poor conversions to anticipated macrolactones. Likewise, product formation with native substrates and hybrid PKS modules bearing non‐cognate TE domains was severely reduced. In contrast, non‐native substrates were converted by most hybrid modules containing a substrate compatible TE, directly implicating this domain as the major catalytic gatekeeper and highlighting its value as a target for protein engineering to improve analog production in PKS pathways.     

D-Fructose-6-phosphate aldolase-catalyzed one-pot synthesis of iminocyclitols

A one-pot chemoenzymatic method for the synthesis of a variety of new iminocyclitols from readily available, non-phosphorylated donor substrates has been developed. The method utilizes the recently discovered fructose-6-phosphate aldolase (FSA), which is functionally distinct from known aldolases in its tolerance of different donor substrates as well as acceptor substrates. Kinetic studies were performed with dihydroxyacetone (DHA), the presumed endogenous substrate for FSA, as well as hydroxy acetone (HA) and 1-hydroxy-2-butanone (HB) as donor substrates, in each case using glyceraldehyde-3-phosphate as acceptor substrate. Remarkably, FSA used the three donor substrates with equal efficiency, with kcat/KMvalues of 33, 75, and 20 M-1 s-1, respectively. This level of donor substrate tolerance is unprecedented for an aldolase. Furthermore, DHA, HA, and HB were accepted as donors in FSA-catalyzed aldol reactions with a variety of azido- and Cbz-amino aldehyde acceptors. The broad substrate tolerance of FSA and the ability to circumvent the need for phosphorylated substrates allowed for one-pot synthesis of a number of known and novel iminocyclitols in good yields, and in a very concise fashion. New iminocyclitols were assayed as inhibitors against a panel of glycosidases. Compounds 15 and 16 were specific alpha-mannosidase inhibitors, and 24 and 26 were potent and selective inhibitors of beta-N-acetylglucosaminidases in the submicromolar range. Facile access to these compounds makes them attractive core structures for further inhibitor optimization.     

Novel Bottom‐Up SERS Substrates for Quantitative and Parallelized Analytics

Surface‐enhanced Raman spectroscopy (SERS) is an emerging technology in the field of analytics. Due to the high sensitivity in connection with specific Raman molecular fingerprint information SERS can be used in a variety of analytical, bioanalytical, and biosensing applications. However, for the SERS effect substrates with metal nanostructures are needed. The broad application of this technology is greatly hampered by the lack of reliable and reproducible substrates. Usually the activity of a given substrate has to be determined by time‐consuming experiments such as calibration or ultramicroscopic studies. To use SERS as a standard analytical tool, cheap and reproducible substrates are required, preferably with a characterization technique that does not interfere with the subsequent measurements. Herein we introduce an innovative approach to produce low‐cost and large‐scale reproducible substrates for SERS applications, which allows easy and economical production of micropatterned SERS active surfaces on a large scale. This approach is based on an enzyme‐induced growth of silver nanostructures. The special structural feature of the enzymatically deposited silver nanoparticles prevents the breakdown of SERS activity even at high particle densities (particle density >60 %) that lead to a conductive layer. In contrast to other approaches, this substrate exhibits a relationship between electrical conductivity and the resulting SERS activity of a given spot. This enables the prediction of the SERS activity of the nanostructure ensemble and therewith the controllable and reproducible production of SERS substrates of enzymatic silver nanoparticles on a large scale, utilizing a simple measurement of the electrical conductivity. Furthermore, through a correlation between the conductivity and the SERS activity of the substrates it is possible to quantify SERS measurements with these substrates.     

An origami paper device for complete elimination of interferents in enzymatic electrochemical biosensors

Many efforts have been made to prevent interferences in enzymatic electrochemical biosensors by permselective membranes or mediators with low redox potential. However, it is difficult to completely eliminate interferents without compromised sensitivity by these traditional procedures. We propose here a method based on an origami paper device that separates the electrochemical reactions of interferents and substrates for complete depletion of interferents and precise analysis of substrates. Interferents such as ascorbate, urate and paracetamol were completely consumed by a simple electrolysis step, while substrates were quantitatively analyzed by coulometry. With GOx as a model enzyme, an interference-free and calibration-free coulometric glucose biosensor has been demonstrated successfully. The proposed origami paper device provides a facile and easy-controlled approach to eliminate the electroactive interferents completely for enzymatic electrochemical biosensors.     

Hydrogen bonding in molecular recognition by HIV-1 protease

Molecular recognition of the cleavage sites of the substrates by HIV-1 protease is analyzed in terms of hydrogen bonding. Crystal structures of an inactive enzyme complexed with six different substrates were used as reference structures. Applying molecular mechanics calculations it can be shown that the interaction energies between the real substrate and the enzyme are larger than with other peptides. From the analysis, it can be concluded that water molecules are essential in the recognition process. Moreover, the hydrogen bonds between the protease and various substrates are characterized in detail.