Name: making conjugation-induced fluorescent pegylated virus-like particles by dibromomaleimide-disulfide chemistry
Uploaded: 2018-05-27T14:00:00
Description: Watch this Scientific Journal Video about Making Conjugation-induced Fluorescent PEGylated Virus-like Particles by Dibromomaleimide-disulfide Chemistry at JoVE.com

J.J.G. acknowledges the National Science foundation (DMR-1654405) and Cancer Prevention Research Institute of Texas (CPRIT) (RP170752s) for their support.

1. Preparation
<ol>
	<li>Make Lysogeny broth (LB) agar and pour plates12.</li>
	<li>Transform BL21(DE3) with a pET28 plasmid containing the wtQ&#946; coat protein sequence.
	<ol>
		<li>Thaw E. coli BL21(DE3) competent cells in an ice bath. Place 50 &#956;L of cells in a microcentrifuge tube.</li>
		<li>Add 2 &#956;L of plasmid into one tube and gently flick the tube. Then incubate on ice for 30 min.</li>
		<li>Heat-shock the cells for 45 s in a water bath that is at exa...

<ol>
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Pouring LB Agar Plates Available from: <a target="_blank" href="https://www.addgene.org/protocols/pouring-lb-agar-plates/">https://www.addgene.org/protocols/pouring-lb-agar-plates/</a> (2016)</li><li>Smith, M., et al. <a target="_blank" href="http://www.ncbi.nlm.nih.gov/entrez/query.fcgi?db=PubMed&cmd=Search&doptcmdl=Citation&defaultField=Title+Word&term=Protein+Modification,+Bioconjugation,+and+Disulfide+Bridging+Using+Bromomaleimides.">Protein Modification, Bioconjugation, and Disulfide Bridging Using Bromomaleimides.</a> J. Am. Chem. 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Compared to smaller protein purification, a unique step in purifying bacteriophage Q&#946; is the sucrose gradient centrifugation. After the chloroform/n-butanol extraction step, Q&#946; is further purified using 5-40% sucrose gradients. During centrifugation, particles are separated based on their sizes. Larger particles travel to the higher density region, while smaller particles stay in the lower density region. Q&#946; travels to the lower third of the gradient and remains there while smaller protein impurities are t...

Using nano-sized viral capsids has emerged as an exciting field, which aims to broaden the scope of applications in biomedical research1,2,3. Recombinantly expressed virus-like particles (VLPs) are structurally derived from viruses, but they lack the original viral genetic material making them non-infectious proteinaceous nanoparticles. As the surface features are genetically programed and each capsid is expressed identically to the ones before and after it, it is possible to know the location and number of reactive side chains of the amino acids with atomistic precision. In many cases, both the exterior and interior surfaces possess many kinds of solvent exposed amino acid residues, which can feasibly be functionalized through bioconjugation reactions - reactions that form covalent bonds between a biomolecule and a synthetic molecule4,5.
Bioconjugation reactions help biomolecules of interest have more diverse functionalities in a relatively straightforward fashion. Molecules of interest, such as therapeutic drugs6, fluorescent tags7 and polymers8,9 can be pre-synthesized and characterized before they are attached on the surface of VLPs. A particularly common VLP in biomedical and biomaterials research has been the VLP based upon Bacteriophage Q&#946;, which, as recombinantly expressed, is a 28 nm icosahedral viral capsid10. The most common reaction sites on Q&#946; are lysines by a wide margin, though we have recently communicated the successful conjugation11 of dibromomaleimide compounds to the reduced disulfides that line the pores of Q&#946; via a Haddleton-Baker reaction. The reaction proceeds with good yield and, equally importantly, without losing the thermal stability of the particles. At the same time, this reaction generates conjugation-induced fluorescence, which can be used to track the uptake of these particles into cells. In this work, we demonstrate the conjugation of polyethylene glycol (PEG) onto the surface of Q&#946; through the Haddleton-Baker reaction, which results in a bright yellow fluorophore. These particles can then be tracked as they are taken in by cells. The protocol herein will help researchers generate new fluorescent PEGylated proteinaceous nanoparticles based upon Q&#946;, though its principles are applicable to one of the many other VLPs containing solvent exposed disulfides.

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			<td height="21" style="height:21px;width:216px;">P10 Pipetman</td>
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			<td height="42" style="height:42px;width:216px;">4&#8211;15% Mini-PROTEAN TGX Gel, 10 well, 50 &#181;l</td>
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making conjugation-induced fluorescent pegylated virus-like particles by dibromomaleimide-disulfide chemistry

The recent rise in virus-like particles (VLPs) in biomedical and materials research can be attributed to their ease of biosynthesis, discrete size, genetic programmability, and biodegradability. While they&#39;re highly amenable to bioconjugation reactions for adding synthetic ligands onto their surface, the range in bioconjugation methodologies on these aqueous born capsids is relatively limited. To facilitate the direction of functional biomaterials research, non-traditional bioconjugation reactions must be considered. The reaction described in this protocol uses dibromomaleimides to introduce new functionality in the solvent exposed disulfide bonds of a VLP based upon Bacteriophage Q&#946;. Furthermore, the final product is fluorescent, which has the added benefit of generating a trackable in vitro probe using a commercially available filter set.

The dibromomaleimide derivatives can be synthesized through the condensation reaction between dibromomaleimide anhydride and primary amines15. Alternatively, a mild synthetic method16 using N-methoxycarbonyl activated 3,4-dibromomaleimide was exploited here by reacting with methoxypolyethylene glycol (PEG) to yield DB-PEG (Figure 1). NMR was used to identify the compound structure (Figure 2<...

Watch this Scientific Journal Video about Making Conjugation-induced Fluorescent PEGylated Virus-like Particles by Dibromomaleimide-disulfide Chemistry at JoVE.com

Making Conjugation-induced Fluorescent PEGylated Virus-like Particles by Dibromomaleimide-disulfide Chemistry

Here, we present a procedure to fluorescently functionalize the disulfides on Q&#946; VLP with dibromomaleimide. We describe Q&#946; expression and purification, the synthesis of dibromomaleimide-functionalized molecules, and the conjugation reaction between dibromomaleimide and Q&#946;. The resulting yellow fluorescent conjugated particle can be used as a fluorescence probe inside cells.

The recent rise in virus-like particles (VLPs) in biomedical and materials research can be attributed to their ease of biosynthesis, discrete size, ...

The overall goal of this bio-conjugation method is to fluorescently functionalize disulfide containing virus-like particles. This method can help answer key questions in the bio-conjugation reaction for virus-like particles which have a limited number of amino acid residues that can be functionalized. The main advantage of this technique is that by using one reaction new functional groups can be introduced and conjugation-induced fluorophores can be formed at the same time.In addition to QBeta, we believe this reaction can be applied to any virus-like particles that possess disulfide bonds. Prior to starting the procedure for expressing the QBeta bacteriophage, wipe down the bench area with a 1:1 bleach:ethanol solution. In an aseptic environment, make two three-milliliter starter cultures by adding single colonies of E.coli BL21 into SOB media.Grow the cultures in a 37 degrees Celsius and 0%relative humidity room with shaking at 250 rpm overnight. On the following day, remove both three-milliliter starter cultures from the shaker and in an aseptic environment pour each starter culture into a two-liter baffled Erlenmeyer flask with one liter of fresh SOB media. Place the two flasks of inoculated media on a shaker at 250 rpm in the 37 degrees Celsius and 0%relative humidity room.Grow the bacteria until they reach an optical density at 600 nanometers or OD 600 of 0.9 to 1.0. This usually takes about five hours. When the cultures are at the desired OD 600, use a P1000 pipette to add one milliliter of one-molar IPTG to each flask to induce protein expression.Leave the flasks on the shaker in the warm room overnight. On the following morning, remove the flasks from the shaker, transfer the contents of each flask to a one-liter bottle, and centrifuge at 20, 621 times gravity at four degrees Celsius for one hour to harvest the cells. When the centrifugation is done, discard the supernatant by pouring it into a flask with about five milliliters of bleach to kill the bacteria.To collect the cell pellet, use a spatula to scrape the cell pellet from the bottom of the centrifuge bottle and transfer the pellet to a 50-milliliter centrifuge tube. To begin the procedure for QBeta purification, re-suspend each cell pellet with 20 to 30 milliliters of 0.1-molar potassium phosphate buffer, pH 7. Make sure the resuspension has no chunks.Lyse the cells using a microfluidizer processor according to the manufacturer's protocol. Lyse the cells at least twice to increase the yield of the particles. Transfer the lysates to 250-milliliter centrifuge bottles and centrifuge at 20, 621 times gravity at four degrees Celsius for one hour.Measure the volume of the supernatant in milliliters. Multiply that value by 0.265 and then add to the supernatant that amount in grams of ammonium sulfate. Add a stir bar and stir on a stir plate at 200 rpm at four degrees Celsius for at least one hour to precipitate out the protein.Centrifuge in 250-milliliter bottles at 20, 621 times gravity at four degrees Celsius for an hour. Discard the supernatant and re-suspend the pellet with about 40 milliliters of 0.1-molar potassium phosphate buffer, pH 7. Add to the crude sample equal volumes of 1:1 chloroform:n-Butanol and mix by vortexing for a few seconds.Transfer the mixture to a 38-milliliter tube. Centrifuge at 20, 621 times gravity at four degrees Celsius for 30 minutes. Use a pipette to recover the top aqueous layer.Be cautious not to take any of the gel-like layer that has formed between the aqueous and organic layers. Next, thaw six 5 to 40%pre-made sucrose gradients. Load about two milliliters of the extract onto each gradient.Ultra-centrifuge at 99, 582 times gravity at four degrees Celsius for 16 hours with free deceleration. When the ultra-centrifugation is complete, shine a light-emitting diode light under each tube to confirm that a blue band is visible. Use a long needle syringe to recover these particles.Ultra-pellet the particles at 370, 541 times gravity at four degrees Celsius for 2.5 hours. The resulting pellet of purified particles should be transparent. Discard the supernatant and re-suspend the pellet with 0.1-molar potassium phosphate buffer, pH 7.This schematic shows the conjugation that will be demonstrated. 10 equivalents of Tris(2-carboxyethyl)phosphine or TCEP relative to the disulfides in one milligram of QBeta is used to reduce all the disulfides to generate the reduced QBeta capsids at room temperature in one hour. Just before the reduction of disulfides on QBeta, prepare a fresh TCEP solution.Dissolve 0.002 grams of TCEP and one milliliter of ultra-pure water to make a 100X stock solution. Add 200 microliters of five milligrams per milliliter QBeta into a microcentrifuge tube. Then, add 20 microliters of the 100X TCEP stock solution to the microcentrifuge tube.Incubate at room temperature for one hour. In the meantime, prepare the dibromomaleimide polyethylene glycol or DB-PEG solution for the later reaction of re-bridging reduced disulfides. Dissolve 0.0017 grams of DB-PEG in 100 microliters of dimethylformamide.Add 680 microliters of 10-millimolar sodium phosphate solution, pH 5. Next, add the reduced QBeta into the solution of DB-PEG and observe the mixing process under a handheld 365-nanometer UV lamp. Upon mixing, a bright yellow fluorescense should be immediately visible.Let the reaction proceed at room temperature on a rotisserie overnight. On the following morning, purify the reaction mixture by centrifugal filter using 1X PBS at 3, 283 times gravity at four degrees Celsius for 20 minutes. Lastly, monitor the conjugation by non-reducing SDS polyacrylamide gel electrophoresis and native agarose-gel electrophoresis.The conjugation of DB-PEG on QBeta was confirmed by non-reducing SDS polyacrylamide gel electrophoresis under UV and Coomassie blue staining. All the fluorescent bands co-localized with the Coomassie blue staining, representing a successful conjugation. The integrity of QBeta-PEG conjugates was confirmed by native agarose gel electrophoresis and transmission electron microscopy.The top micrograph shows QBeta-maleimide or QBeta-M and the bottom micrograph shows QBeta-PEG. Fluorescence spectroscopy of QBeta-M and QBeta-PEG in 0.1 molar of potassium phosphate buffer showed an excitation maximum around 400 nanometers and an emission maximum around 540 to 550 nanometers. When QBeta-PEG was incubated with mouse macrophage cells in serum-free DMEM medium followed by nucleostaining, co-localization images show that yellow fluorescent particles were taken up by the cells and can be tracked after four hours of incubation.In contrast, the unfunctionalized QBeta virus-like particles show negligible fluorescense. This protocol can help researchers purify QBeta in four days and perform the overnight re-bridging conjugation reaction. While attempting this procedure, it's important to remember that the conjugation reaction works best under acidic conditions, such as pH 5.After watching this video, you should have a good understanding of how to purify QBeta VLP and re-bridge the disulfide bonds with dibromomaleimide compounds to make a fluorescently-labeled VLP. After its development, this technique provided researchers an additional functional handle which can be used to dual-functionalize the exterior surface of bacteriophage QBeta.

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Bioengineering

A Microfluidic-based Hydrodynamic Trap for Single Particles

The ability to confine and manipulate single particles in free solution is a key enabling technology for fundamental and applied science. Methods for particle trapping based on optical, magnetic, electrokinetic, and acoustic techniques have led to major advancements in physics and biology ranging from the molecular to cellular level. In this article, we introduce a new microfluidic-based technique for particle trapping and manipulation based solely on hydrodynamic fluid flow. Using this method, we demonstrate trapping of micro- and nano-scale particles in aqueous solutions for long time scales. The hydrodynamic trap consists of an integrated microfluidic device with a cross-slot channel geometry where two opposing laminar streams converge, thereby generating a planar extensional flow with a fluid stagnation point (zero-velocity point). In this device, particles are confined at the trap center by active control of the flow field to maintain particle position at the fluid stagnation point. In this manner, particles are effectively trapped in free solution using a feedback control algorithm implemented with a custom-built LabVIEW code. The control algorithm consists of image acquisition for a particle in the microfluidic device, followed by particle tracking, determination of particle centroid position, and active adjustment of fluid flow by regulating the pressure applied to an on-chip pneumatic valve using a pressure regulator. In this way, the on-chip dynamic metering valve functions to regulate the relative flow rates in the outlet channels, thereby enabling fine-scale control of stagnation point position and particle trapping. The microfluidic-based hydrodynamic trap exhibits several advantages as a method for particle trapping. Hydrodynamic trapping is possible for any arbitrary particle without specific requirements on the physical or chemical properties of the trapped object. In addition, hydrodynamic trapping enables confinement of a "single" target object in concentrated or crowded particle suspensions, which is difficult using alternative force field-based trapping methods. The hydrodynamic trap is user-friendly, straightforward to implement and may be added to existing microfluidic devices to facilitate trapping and long-time analysis of particles. Overall, the hydrodynamic trap is a new platform for confinement, micromanipulation, and observation of particles without surface immobilization and eliminates the need for potentially perturbative optical, magnetic, and electric fields in the free-solution trapping of small particles.

In this article, we present a microfluidic-based method for particle confinement based on hydrodynamic flow. We demonstrate stable particle trapping at a fluid stagnation point using a feedback control mechanism, thereby enabling confinement and micromanipulation of arbitrary particles in an integrated microdevice.

The ability to confine and manipulate single particles in free solution is a key enabling technology for fundamental and applied science.  Methods for ...

Thermodynamics of Membrane Protein Folding Measured by Fluorescence Spectroscopy

Membrane protein folding is an emerging topic with both fundamental and health-related significance. The abundance of membrane proteins in cells underlies the need for comprehensive study of the folding of this ubiquitous family of proteins. Additionally, advances in our ability to characterize diseases associated with misfolded proteins have motivated significant experimental and theoretical efforts in the field of protein folding. Rapid progress in this important field is unfortunately hindered by the inherent challenges associated with membrane proteins and the complexity of the folding mechanism. Here, we outline an experimental procedure for measuring the thermodynamic property of the Gibbs free energy of unfolding in the absence of denaturant, &Delta;G&deg;H2O, for a representative integral membrane protein from E. coli. This protocol focuses on the application of fluorescence spectroscopy to determine equilibrium populations of folded and unfolded states as a function of denaturant concentration. Experimental considerations for the preparation of synthetic lipid vesicles as well as key steps in the data analysis procedure are highlighted. This technique is versatile and may be pursued with different types of denaturant, including temperature and pH, as well as in various folding environments of lipids and micelles. The current protocol is one that can be generalized to any membrane or soluble protein that meets the set of criteria discussed below.

This video article details the experimental procedure for obtaining the Gibbs free energy of membrane protein folding by tryptophan fluorescence.

Membrane protein folding is an emerging topic with both fundamental and health-related significance.  The abundance of membrane proteins in cells ...

Imaging of Biological Tissues by Desorption Electrospray Ionization Mass Spectrometry

Mass spectrometry imaging (MSI) provides untargeted molecular information with the highest specificity and spatial resolution for investigating biological tissues at the hundreds to tens of microns scale. When performed under ambient conditions, sample pre-treatment becomes unnecessary, thus simplifying the protocol while maintaining the high quality of information obtained. Desorption electrospray ionization (DESI) is a spray-based ambient MSI technique that allows for the direct sampling of surfaces in the open air, even in vivo. When used with a software-controlled sample stage, the sample is rastered underneath the DESI ionization probe, and through the time domain, m/z information is correlated with the chemical species' spatial distribution. The fidelity of the DESI-MSI output depends on the source orientation and positioning with respect to the sample surface and mass spectrometer inlet. Herein, we review how to prepare tissue sections for DESI imaging and additional experimental conditions that directly affect image quality. Specifically, we describe the protocol for the imaging of rat brain tissue sections by DESI-MSI.

Desorption electrospray ionization mass spectrometry (DESI-MS) is an ambient method by which samples, including biological tissues, can be imaged with minimal sample preparation. By rastering the sample below the ionization probe, this spray-based technique provides sufficient spatial resolution to discern molecular features of interest within tissue sections.

Mass spectrometry imaging (MSI) provides untargeted molecular information with the highest specificity and spatial resolution for investigating biological ...

Intra-lymph Node Injection of Biodegradable Polymer Particles

Generation of adaptive immune response relies on efficient drainage or trafficking of antigen to lymph nodes for processing and presentation of these foreign molecules to T and B lymphocytes. Lymph nodes have thus become critical targets for new vaccines and immunotherapies. A recent strategy for targeting these tissues is direct lymph node injection of soluble vaccine components, and clinical trials involving this technique have been promising. Several biomaterial strategies have also been investigated to improve lymph node targeting, for example, tuning particle size for optimal drainage of biomaterial vaccine particles. In this paper we present a new method that combines direct lymph node injection with biodegradable polymer particles that can be laden with antigen, adjuvant, or other vaccine components. In this method polymeric microparticles or nanoparticles are synthesized by a modified double emulsion protocol incorporating lipid stabilizers. Particle properties (e.g.&#160;size, cargo loading) are confirmed by laser diffraction and fluorescent microscopy, respectively. Mouse lymph nodes are then identified by peripheral injection of a nontoxic tracer dye that allows visualization of the target injection site and subsequent deposition of polymer particles in lymph nodes. This technique allows direct control over the doses and combinations of biomaterials and vaccine components delivered to lymph nodes and could be harnessed in the development of new biomaterial-based vaccines.

Lymph nodes are the immunological tissues that orchestrate immune response and are a critical target for vaccines. Biomaterials have been employed to better target lymph nodes and to control delivery of antigens or adjuvants. This paper describes a technique combining these ideas to inject biocompatible polymer particles into lymph nodes.

Generation of adaptive immune response relies on efficient drainage or trafficking of antigen to lymph nodes for processing and presentation of these ...

Circulating MicroRNA Quantification Using DNA-binding Dye Chemistry and Droplet Digital PCR

Circulating (of cell-free) microRNAs (miRNAs) are released from cells into the blood stream. The amount of specific microRNAs in the circulation has been linked to a disease state and has the potential to be used as disease biomarker. A sensitive and accurate method for circulating microRNA quantification using a dye-based chemistry and droplet digital PCR technology has been recently developed. Specifically, using Locked Nucleic Acid (LNA)-based miRNA-specific primers with a green fluorescent DNA-binding dye in a compatible droplet digital PCR system it is possible to obtain the absolute quantification of specific miRNAs. Here, we describe how performing this technique to assess miRNA amount in biological fluids, such as plasma and serum, is both feasible and effective.

A sensitive and accurate method for cell-free microRNAs quantification using a dye-based chemistry and droplet digital PCR technology is described.

Circulating (of cell-free) microRNAs (miRNAs) are released from cells into the blood stream. The amount of specific microRNAs in the circulation has been ...

Determination of Zeta Potential via Nanoparticle Translocation Velocities through a Tunable Nanopore: Using DNA-modified Particles as an Example

Nanopore technologies, known collectively as Resistive Pulse Sensors (RPS), are being used to detect, quantify and characterize proteins, molecules and nanoparticles. Tunable resistive pulse sensing (TRPS) is a relatively recent adaptation to RPS that incorporates a tunable pore that can be altered in real time. Here, we use TRPS to monitor the translocation times of DNA-modified nanoparticles as they traverse the tunable pore membrane as a function of DNA concentration and structure (i.e., single-stranded to double-stranded DNA).
TRPS is based on two Ag/AgCl electrodes, separated by an elastomeric pore membrane that establishes a stable ionic current upon an applied electric field. Unlike various optical-based particle characterization technologies, TRPS can characterize individual particles amongst a sample population, allowing for multimodal samples to be analyzed with ease. Here, we demonstrate zeta potential measurements via particle translocation velocities of known standards and apply these to sample analyte translocation times, thus resulting in measuring the zeta potential of those analytes.
As well as acquiring mean zeta potential values, the samples are all measured using a particle-by-particle perspective exhibiting more information on a given sample through sample population distributions, for example. Of such, this method demonstrates potential within sensing applications for both medical and environmental fields.

Here we use a polyurethane tunable nanopore integrated into a resistive pulse sensing technique to characterize nanoparticles surface chemistry via the measurement of particle translocation velocities, which can be used to determine the zeta potential of individual nanoparticles.

Nanopore technologies, known collectively as Resistive Pulse Sensors (RPS), are being used to detect, quantify and characterize proteins, molecules and ...

Microfluidic Platform with Multiplexed Electronic Detection for Spatial Tracking of Particles

Microfluidic processing of biological samples typically involves differential manipulations of suspended particles under various force fields in order to spatially fractionate the sample based on a biological property of interest. For the resultant spatial distribution to be used as the assay readout, microfluidic devices are often subjected to microscopic analysis requiring complex instrumentation with higher cost and reduced portability. To address this limitation, we have developed an integrated electronic sensing technology for multiplexed detection of particles at different locations on a microfluidic chip. Our technology, called Microfluidic CODES, combines Resistive Pulse Sensing with Code Division Multiple Access to compress 2D spatial information into a 1D electrical signal. In this paper, we present a practical demonstration of the Microfluidic CODES technology to detect and size cultured cancer cells distributed over multiple microfluidic channels. As validated by the high-speed microscopy, our technology can accurately analyze dense cell populations all electronically without the need for an external instrument. As such, the Microfluidic CODES can potentially enable low-cost integrated lab-on-a-chip devices that are well suited for the point-of-care testing of biological samples.

We demonstrate a microfluidic platform with an integrated surface electrode network that combines resistive pulse sensing (RPS) with code division multiple access (CDMA), to multiplex detection and sizing of particles in multiple microfluidic channels.

Microfluidic processing of biological samples typically involves differential manipulations of suspended particles under various force fields in order to ...

Trapping of Micro Particles in Nanoplasmonic Optical Lattice

The plasmonic optical tweezer has been developed to overcome the diffraction limits of the conventional far field optical tweezer. Plasmonic optical lattice consists of an array of nanostructures, which exhibit a variety of trapping and transport behaviors. We report the experimental procedures to trap micro-particles in a simple square nanoplasmonic optical lattice. We also describe the optical setup and the nanofabrication of a nanoplasmonic array. The optical potential is created by illuminating an array of gold nanodiscs with a Gaussian beam of 980 nm wavelength, and exciting plasmon resonance. The motion of particles is monitored by fluorescence imaging. A scheme to suppress photothermal convection is also described to increase usable optical power for optimal trapping. Suppression of convection is achieved by cooling the sample to a low temperature, and utilizing the near-zero thermal expansion coefficient of a water medium. Both single particle transport and multiple particle trapping are reported here.

We describe a procedure to optically trap micro-particles in nanoplasmonic optical lattice.

The plasmonic optical tweezer has been developed to overcome the diffraction limits of the conventional far field optical tweezer. Plasmonic optical ...

Site-Directed Immobilization of Bone Morphogenetic Protein 2 to Solid Surfaces by Click Chemistry

Different therapeutic strategies for the treatment of non-healing long bone defects have been intensively investigated. Currently used treatments present several limitations that have led to the use of biomaterials in combination with osteogenic growth factors, such as bone morphogenetic proteins (BMPs). Commonly used absorption or encapsulation methods require supra-physiological amounts of BMP2, typically resulting in a so-called initial burst release effect that provokes several severe adverse side effects. A possible strategy to overcome these problems would be to covalently couple the protein to the scaffold. Moreover, coupling should be performed in a site-specific manner in order to guarantee a reproducible product outcome. Therefore, we created a BMP2 variant, in which an artificial amino acid (propargyl-L-lysine) was introduced into the mature part of the BMP2 protein by codon usage expansion (BMP2-K3Plk). BMP2-K3Plk was coupled to functionalized beads through copper catalyzed azide-alkyne cycloaddition (CuAAC). The biological activity of the coupled BMP2-K3Plk was proven in vitro and the osteogenic activity of the BMP2-K3Plk-functionalized beads was proven in cell based assays. The functionalized beads in contact with C2C12 cells were able to induce alkaline phosphatase (ALP) expression in locally restricted proximity of the bead. Thus, by this technique, functionalized scaffolds can be produced that can trigger cell differentiation towards an osteogenic lineage. Additionally, lower BMP2 doses are sufficient due to the controlled orientation of site-directed coupled BMP2. With this method, BMPs are always exposed to their receptors on the cell surface in the appropriate orientation, which is not the case if the factors are coupled via non-site-directed coupling techniques. The product outcome is highly controllable and, thus, results in materials with homogeneous properties, improving their applicability for the repair of critical size bone defects.

Biomaterials doped with Bone Morphogenetic Protein 2 (BMP2) have been used as a new therapeutic strategy to heal non-union bone fractures. To overcome side effects resulting from an uncontrollable release of the factor, we propose a new strategy to site-directly immobilize the factor, thus creating materials with improved osteogenic capabilities.

Different therapeutic strategies for the treatment of non-healing long bone defects have been intensively investigated. Currently used treatments present ...

Engineering 'Golden' Fluorescence by Selective Pressure Incorporation of Non-canonical Amino Acids and Protein Analysis by Mass Spectrometry and Fluorescence

Fluorescent proteins are fundamental tools for the life sciences, in particular for fluorescence microscopy of living cells. While wild-type and engineered variants of the green fluorescent protein from Aequorea victoria (avGFP) as well as homologs from other species already cover large parts of the optical spectrum, a spectral gap remains in the near-infrared region, for which avGFP-based fluorophores are not available. Red-shifted fluorescent protein (FP) variants would substantially expand the toolkit for spectral unmixing of multiple molecular species, but the naturally occurring red-shifted FPs derived from corals or sea anemones have lower fluorescence quantum yield and inferior photo-stability compared to the avGFP variants. Further manipulation and possible expansion of the chromophore&#39;s conjugated system towards the far-red spectral region is also limited by the repertoire of 20 canonical amino acids prescribed by the genetic code. To overcome these limitations, synthetic biology can achieve further spectral red-shifting via insertion of non-canonical amino acids into the chromophore triad. We describe the application of SPI to engineer avGFP variants with novel spectral properties. Protein expression is performed in a tryptophan-auxotrophic E. coli strain and by supplementing growth media with suitable indole precursors. Inside the cells, these precursors are converted to the corresponding tryptophan analogs and incorporated into proteins by the ribosomal machinery in response to UGG codons. The replacement of Trp-66 in the enhanced &#34;cyan&#34; variant of avGFP (ECFP) by an electron-donating 4-aminotryptophan results in GdFP featuring a 108 nm Stokes shift and a strongly red-shifted emission maximum (574 nm), while being thermodynamically more stable than its predecessor ECFP. Residue-specific incorporation of the non-canonical amino acid is analyzed by mass spectrometry. The spectroscopic properties of GdFP are characterized by time-resolved fluorescence spectroscopy as one of the valuable applications of genetically encoded FPs in life sciences.

Engineering &#039;Golden&#039; Fluorescence by Selective Pressure Incorporation of Non-canonical Amino Acids and Protein Analysis by Mass Spectrometry and Fluorescence

Synthetic biology enables the engineering of proteins with unprecedented properties using the co-translational insertion of non-canonical amino acids. Here, we presented how a spectrally red-shifted variant of a GFP-type fluorophore with novel fluorescence spectroscopic properties, termed &#34;gold&#34; fluorescent protein (GdFP), is produced in E. coli via selective pressure incorporation (SPI).