We report here on the genome sequence of Pasteurella multocida Razi 0002 of avian origin, isolated in Iran. The genome has a size of 2,289,036 bp, a GC content of 40.3%, and is predicted to contain 2,079 coding sequences.
Zero-mode waveguides provide a powerful technology for studying single-molecule real-time dynamics of biological systems at physiological ligand concentrations. We customized a commercial zero-mode waveguide-based DNA sequencer for use as a versatile instrument for single-molecule fluorescence detection and showed that the system provides long fluorophore lifetimes with good signal to noise and low spectral cross-talk. We then used a ribosomal translation assay to show real-time fluidic delivery during data acquisition, showing it is possible to follow the conformation and composition of thousands of single biomolecules simultaneously through four spectral channels. This instrument allows high-throughput multiplexed dynamics of single-molecule biological processes over long timescales. The instrumentation presented here has broad applications to single-molecule studies of biological systems and is easily accessible to the biophysical community.D etermining the molecular details of the time evolution of complex multicomponent biological systems requires analysis at the single-molecule level because of their stochastic and heterogeneous nature. Ideally, such experiments would track simultaneously the composition of a biological system (bound ligands, factors, and cofactors) and the conformation of the individual molecules in real time. Single-molecule fluorescence methods, such as total internal reflection fluorescence (TIRF) microscopy, allow the observations of the compositional dynamics (through arrival of fluorescently labeled ligands, factors, or cofactors) and conformational dynamics (through FRET) of single-molecular species. However, these traditional singlemolecule methods are hindered by limitations in maximal fluorescent component concentrations (up to 50 nM) (1), limited simultaneous detection (two to three colors) (2-6), and low throughput (a few hundred molecules at most per experiment) (7). As such, the full potential of single-molecule fluorescence to investigate a range of biological problems under physiologically relevant conditions has not yet been harnessed.Zero-mode waveguides (ZMWs) are small metallic apertures patterned on glass substrates that overcome the concentration restrictions by optically limiting background excitation (8). Each ZMW consists of an ∼150-nm-diameter metallic aperture that restricts the excitation light to a zeptoliter volume, making possible experiments with near-physiological concentrations (up to 20 μM) of fluorescently labeled ligands (1). Previous advances in nanofabrication (9), surface chemistry (10), and detection instrumentation (11) have led to ZMW-based instrumentation capable of the direct observation of DNA polymerization (12), reverse transcription (13), processive myosin motion (14), and translation by the ribosome (15, 16) with multicolor single-molecule detection. However, this sophisticated technology has not been broadly available to the scientific community. Despite multiple efforts to develop ZMW instrumentation, the combined difficulties in fabrica...
The performance of amorphous organic photorefractive (PR) materials in applications such as optical data storage is generally limited by the concentration of active molecules (chromophores) that can be incorporated into the host without forming a crystalline material with poor optical quality. In polymeric PR systems described previously, performance has been limited by the necessity of devoting a large fraction of the material to inert polymer and plasticizing components in order to ensure compositional stability. A new class of organic PR materials composed of multifunctional glass-forming organic chromophores is described that have long-term stability and greatly improved PR properties.
Metallic subwavelength apertures can be used in epi-illumination fluorescence to achieve focal volume confinement. Because of the near field components inherent to small metallic structures, observation volumes are formed that are much smaller than the conventional diffraction limited volume attainable by high numerical aperture far field optics ͑circa a femtoliter͒. Observation volumes in the range of 10 −4 fl have been reported previously. Such apertures can be used for single-molecule detection at relatively high concentrations ͑up to 20 M͒ of fluorophores. Here, we present a novel fabrication of metallic subwavelength apertures in the visible range. Using a new electron beam lithography process, uniform arrays of such apertures can be manufactured efficiently in large numbers with diameters in the range of 60-100 nm. The apertures were characterized by scanning electron microscopy, optical microscopy, focused ion beam cross sections/transmission electron microscopy, and fluorescence correlation spectroscopy measurements, which confirmed their geometry and optical confinement. Process throughput can be further increased using deep ultraviolet photolithography to replace electron beam lithography. This enables the production of aperture arrays in a high volume manufacturing environment.
The confocal detection principle is extended to a highly parallel optical system that continuously analyzes thousands of concurrent sample locations. This is achieved through the use of a holographic laser illumination multiplexer combined with a confocal pinhole array before a prism dispersive element used to provide spectroscopic information from each confocal volume. The system is demonstrated to detect and identify single fluorescent molecules from each of several thousand independent confocal volumes in real time.
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