Many cases of influenza are reported worldwide every year. The influenza virus often acquires new antigenicity, which is known as antigenic shift; this results in the emergence of new virus strains, for which preexisting immunity is not found in the population resulting in influenza pandemics. In the event a new strain emerges, diagnostic tools must be developed rapidly to detect the novel influenza strain. The generation of high affinity antibodies is costly and takes time; therefore, an alternative detection system, aptamer detection, provides a viable alternative to antibodies as a diagnostic tool. In this study, we developed DNA aptamers that bind to HA1 proteins of multiple influenza A virus subtypes by the SELEX procedure. To evaluate the binding properties of these aptamers using colorimetric methods, we developed a novel aptamer-based sandwich detection method employing our newly identified aptamers. This novel sandwich enzyme-linked aptamer assay successfully detected the H5N1, H1N1, and H3N2 subtypes of influenza A virus with almost equal sensitivities. These findings suggest that our aptamers are attractive candidates for use as simple and sensitive diagnostic tools that need sandwich system for detecting the influenza A virus with broad subtype specificities.
L-Methionine gamma-lyase (MGL) catalyzes the pyridoxal 5'-phosphate (PLP) dependent alpha,gamma-elimination of L-methionine. We have determined two crystal structures of MGL from Pseudomonas putida using MAD (multiwavelength anomalous diffraction) and molecular replacement methods. The structures have been refined to an R-factor of 21.1% at 2.0 and 1.7 A resolution using synchrotron radiation diffraction data. A homotetramer with 222 symmetry is built up by non-crystallographic symmetry. Two monomers associate to build the active dimer. The spatial fold of subunits, with three functionally distinct domains and their quarternary arrangement, is similar to those of L-cystathionine beta-lyase and L-cystathionine gamma-synthase from Escherichia coli.
Florescent proteins have been popularly used for studying genes and proteins of interest in various experiments at a cellular level, such as the analysis of intracellular localization and protein-protein interaction. However, the strength of fluorescence was insufficient for macro level observations of tissues or of the whole plant, and the fluorescent flowers that have been generated so far needed high-sensitive imaging equipment for the observation. Here we generated fluorescent Torenia flowers by the combined use of a high-performance fluorescent protein and the latest protein expression technologies, leading to the production of fluorescent proteins that can be easily and clearly observed. A coding sequence of a yellowish green fluorescent protein from the marine plankton Chiridius poppei (CpYGFP) was fused to the optimized sequences of the heat shock protein terminator and the 5′-untranslated region of the alcohol dehydrogenase gene of Arabidopsis to gain massive accumulation of the fluorescent protein. Strong fluorescence of CpYGFP was apparent in every part of the transgenic plant under the simple combination of a blue LED for excitation and an orange colored transparent acrylic filter for emission, while faint autofluorescence remained in the wild-type plants. By evaluating the combination of excitation wavelengths (excitation and emission filters) we were able to eliminate this undesired fluorescence. The fluorescent flowers could be used for ornamental purposes as well as for the analysis of fluorescent transgenic plants spatiotemporally in a nondestructive manner.
Nucleic acid amplification techniques were applied to the enzyme linked immunosorbent assay (ELISA) with an antibody-specific aptamer, R18. This novel detection system is a modification of the original immuno-polymerase chain reaction (immuno-PCR), but oligonucleotide-labeled antibodies are not required in the assay. This method is performed with the usual ELISA protocol, using an RNA aptamer for rabbit IgG instead of the conventional secondary antibody. After the assay plate was washed, quantitative reverse transcription (RT)-PCR was performed. Ribonuclease (RNase) inhibitors are not needed for this method. The detection limit of the quantitative RT-PCR is over 100 times more sensitive than the original ELISA method, even with the same sandwich-antibody combination. Only 1 mg of aptamer is sufficient for more than 10 million assays. This aptamer-based quantitative PCR successfully detected 16 attomoles (16 x 10(-18)) of vascular endothelial growth factor (VEGF). This is a cost-effective and easy method to increase the sensitivity of the rabbit antibody-based ELISA systems. The new method is referred to as immuno-aptamer PCR (iaPCR), to distinguish it from the original immuno-PCR.
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