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Labeled Proteins (labeled + protein)

Distribution by Scientific Domains
Life Sciences60%

Selected Abstracts

Tailored Plasmonic Gratings for Enhanced Fluorescence Detection and Microscopic Imaging

ADVANCED FUNCTIONAL MATERIALS, Issue 4 2010
Xiaoqiang Cui
Abstract The ability to precisely control the pattern of metallic structures at the micro- and nanoscale for surface plasmon coupling has been demonstrated to be essential for signal enhancement in fields such as fluorescence and surface-enhanced Raman scattering. In the present study, a series of silver coated gratings with tailored duty ratio and depth and a periodical pitch of 400,nm are designed and implemented. The influence of the grating profile on plasmonic properties and the corresponding enhancement factor are investigated by angular scanning measurement of reflectivity and fluorescence intensity and by finite difference time domain simulation. The application of the substrate in the enhanced fluorescence imaging detection of labeled protein is also investigated. This substrate has a wide range of potential applications in areas including biodiagnostics, imaging, sensing, and photovoltaic cells. [source]

Probing events with single molecule sensitivity in zebrafish and Drosophila embryos by fluorescence correlation spectroscopy

DEVELOPMENTAL DYNAMICS, Issue 12 2009
Xianke Shi
Abstract Zebrafish and Drosophila are animal models widely used in developmental biology. High-resolution microscopy and live imaging techniques have allowed the investigation of biological processes down to the cellular level in these models. Here, using fluorescence correlation spectroscopy (FCS), we show that even processes on a molecular level can be studied in these embryos. The two animal models provide different advantages and challenges. We first characterize their autofluorescence pattern and determine usable penetration depth for FCS especially in the case of zebrafish, where tissue thickness is an issue. Next, the applicability of FCS to study molecular processes is shown by the determination of blood flow velocities with high spatial resolution and the determination of diffusion coefficients of cytosolic and membrane-bound enhanced green fluorescent protein,labeled proteins in different cell types. This work provides an approach to study molecular processes in vivo and opens up the possibility to relate these molecular processes to developmental biology questions. Developmental Dynamics 238:3156,3167, 2009. © 2009 Wiley-Liss, Inc. [source]

Subcellular localization of proteins labeled with GFP in Xanthomonas citri ssp. citri: targeting the division septum

FEMS MICROBIOLOGY LETTERS, Issue 1 2010
Paula M.M. Martins
Abstract Xanthomonas citri ssp. citri (Xac) is the causal agent of citrus canker, an economically important disease that affects citrus worldwide. To initiate the characterization of essential biological processes of Xac, we constructed integrative plasmids for the ectopic expression of green fluorescent protein (GFP)-labeled proteins within this bacterium. Here, we show that the disruption of the ,-amylase gene (amy), the site of plasmid integration into the bacterial chromosome, does not alter its pathogenesis while abolishing completely the ability of Xac to degrade starch. Furthermore, our GFP expression system was used to characterize ORF XAC3408, a hypothetical protein encoded by Xac that shares significant homology to the FtsZ-stabilizing factor ZapA from Bacillus subtilis (ZapABsu). GFP-XAC3408 expressed in Xac exhibited a septal localization pattern typical of GFP-ZapABsu, which indicates that XAC3408 is the Xac orthologue of the cell division protein ZapABsu. The results demonstrate the potential of GFP labeling for protein functional characterizations in Xac, and, in addition, the Xac mutant strain labeled at the septum constitutes a biological model for the exploration of antibacterial compounds able to inhibit cell division in this plant pathogen. [source]

Rapid and selective isolation of ,-xylosidase through an activity-based chemical approach

BIOTECHNOLOGY JOURNAL, Issue 2 2006
Lee-Chiang Lo Dr.
Abstract ,-Xylosidase is a key enzyme in the xylanolytic system with a great potential in many biotechnological applications, especially in the food as well as the pulp and paper industries. We have developed a chemical approach for the rapid screening and isolation of ,-xylosidase. Activity probe LCL-6X targeting ,-xylosidase was utilized in this study. It carries a ,-xylopyranosyl recognition head, a latent trapping device consisting of a 2-fluoromethylphenoxyl group, and a biotin reporter group. The biotin reporter group serves both as a readout device and as a tool for enriching the labeled proteins. LCL-6X could selectively label a model ,-xylosidase from Trichoderma koningii. All other bystander proteins used in this study, including phosphorylase b, BSA, ovalbumin, carbonic anhydrase, and trypsin inhibitor, gave negligible cross-labeling effect. With the assistance of streptavidin agarose beads and mass spectrophotometry for the recovery and identification of the biotinylated proteins, we demonstrated that LCL-6X could be successfully applied to identify a bi-functional enzyme with ,- L -arabinofuranosidase/,-xylosidase activity from the total protein extract of a Pichia expressing system and a prospective ,-xylosidase in the culture medium of Aspergillus fumigatus. The ,-xylosidase activities from numerous microbes were also screened using the LCL-6X probe. Preliminary results showed significant differences among these microbial sources and some distinct protein bands were observed. Thus, we have successfully developed a novel chemical probe that has potential applications in xylan-related research. [source]

Protocols for the Sequential Solid-State NMR Spectroscopic Assignment of a Uniformly Labeled 25 kDa Protein: HET-s(1-227)

CHEMBIOCHEM, Issue 11 2010
Anne Schuetz
Abstract The sequence-specific resonance assignment of a protein forms the basis for studies of molecular structure and dynamics, as well as to functional assay studies by NMR spectroscopy. Here we present a protocol for the sequential 13C and 15N resonance assignment of uniformly [15N,13C]-labeled proteins, based on a suite of complementary three-dimensional solid-state NMR spectroscopy experiments. It is directed towards the application to proteins with more than about 100 amino acid residues. The assignments rely on a walk along the backbone by using a combination of three experiments that correlate nitrogen and carbon spins, including the well-dispersed C, resonances. Supplementary spectra that correlate further side-chain resonances can be important for identifying the amino acid type, and greatly assist the assignment process. We demonstrate the application of this assignment protocol for a crystalline preparation of the N-terminal globular domain of the HET-s prion, a 227-residue protein. [source]