Real-time, single-molecule observation of biomolecular interactions inside nanophotonic zero mode waveguides.

Living cells rely on numerous protein-protein, RNA-protein and DNA-protein interactions for processes such as gene expression, biomolecular assembly, protein and RNA degradation. Single-molecule microscopy and spectroscopy are ideal tools for real-time observation and quantification of nucleic acids-protein and protein-protein interactions. One of the major drawbacks of conventional single-molecule imaging methods is low throughput. Methods such as sequencing by synthesis utilizing nanofabrication and single-molecule spectroscopy have brought high throughput into the realm of single-molecule biology. The Pacific Biosciences RS2 sequencer utilizes sequencing by synthesis within nanophotonic zero mode waveguides. A number of years ago this instrument was unlocked by Pacific Biosciences for custom use by researchers allowing them to monitor biological interactions at the single-molecule level with high throughput. In this capability letter we demonstrate the use of the RS2 sequencer for real-time observation of DNA-to-RNA transcription and RNA-protein interactions. We use a relatively complex model-transcription of structured ribosomal RNA fromE. coliand interactions of ribosomal RNA with ribosomal proteins. We also show evidence of observation of transcriptional pausing without the application of an external force (as is required for single-molecule pausing studies using optical traps). Overall, in the unlocked, custom mode, the RS2 sequencer can be used to address a wide variety of biological assembly and interaction questions at the single-molecule level with high throughput. This instrument is available for use at the Center for Integrated Nanotechnologies Gateway located at Los Alamos National Laboratory.

Note: Time-gated 3D single quantum dot tracking with simultaneous spinning disk imaging.

We describe recent upgrades to a 3D tracking microscope to include simultaneous Nipkow spinning disk imaging and time-gated single-particle tracking (SPT). Simultaneous 3D molecular tracking and spinning disk imaging enable the visualization of cellular structures and proteins around a given fluorescently labeled target molecule. The addition of photon time-gating to the SPT hardware improves signal to noise by discriminating against Raman scattering and short-lived fluorescence. In contrast to camera-based SPT, single-photon arrival times are recorded, enabling time-resolved spectroscopy (e.g., measurement of fluorescence lifetimes and photon correlations) to be performed during single molecule/particle tracking experiments.

Interferometric three-dimensional single molecule localization microscopy using a single high-numerical-aperture objective.

Interferometric detection of the fluorescence emission from a single molecule [interferometric photoactivated localization microscopy (iPALM)] enables a localization accuracy of nanometers in axial localization for 3D superresolution imaging. However, iPALM uses two high-numerical-aperture (NA) objectives in juxtaposition for fluorescence collection (a 4Pi microscope geometry), increasing expense and limiting samples that can be studied. Here, we propose an interferometric single molecule localization microscopy method using a single high-NA objective. The axial position of single molecules can be unambiguously determined from the phase-shifted interference signals with nanometer precision and over a range of 2λ. The use of only one objective simplifies the system configuration and sample mounting. In addition, due to the use of wavefront-splitting interference in our approach, the two parts of the wavefront that eventually merge and interfere with each other travel along nearly equivalent optical paths, which should minimize the effect of drift for long-term 3D superresolution imaging.

Confocal line scanning of a Bessel beam for fast 3D imaging.

We have developed a light-sheet illumination microscope that can perform fast 3D imaging of transparent biological samples with inexpensive visible lasers and a single galvo mirror (GM). The light-sheet is created by raster scanning a Bessel beam with a GM, with this same GM also being used to rescan the fluorescence across a chip of a camera to construct an image in real time. A slit is used to reject out-of-focus fluorescence such that the image formed in real time has minimal contribution from the sidelobes of the Bessel beam. Compared with two-photon Bessel beam excitation or other confocal line-scanning approaches, our method is of lower cost, is simpler, and does not require calibration and synchronization of multiple GMs. We demonstrated the optical sectioning and out-of-focus background rejection capabilities of this microscope by imaging fluorescently labeled actin filaments in fixed 3T3 cells.

Fast, super resolution imaging via Bessel-beam stimulated emission depletion microscopy.

A substantial advantage of stimulated emission depletion (STED) microscopy over other super-resolution methods is that images can be acquired in real-time without any post-processing. However imaging speed and photodamage are two major concerns for STED imaging of whole cells. Here we propose a new microscopy method we have termed Bessel-Beam STED (or BB-STED) that overcomes both of these limitations of conventional STED microscopy. In the proposed method, rather than exciting a single STED spot in the sample, an entire line of the sample is illuminated. This line-scanning technique dramatically increases the speed of STED. In addition, plane-illumination by scanning of the line across the focal plane of a detection objective limits the light to a thin layer of the sample and thus significantly reduces photobleaching and photodamage above and below the focal plane compared to epi-illumination. Using the organic dye Atto647N as an example, we calculated the STED power required to break the diffraction limit. The results presented here will be used to guide future experimental designs.

Site-directed mutagenesis and X-ray crystallography of the PQQ-containing quinoprotein methanol dehydrogenase and its electron acceptor, cytochrome c(L).

Two proteins specifically involved in methanol oxidation in the methylotrophic bacterium Methylobacterium extorquens have been modified by site-directed mutagenesis. Mutation of the proposed active site base (Asp303) to glutamate in methanol dehydrogenase (MDH) gave an active enzyme (D303E-MDH) with a greatly reduced affinity for substrate and with a lower activation energy. Results of kinetic and deuterium isotope studies showed that the essential mechanism in the mutant protein was unchanged, and that the step requiring activation by ammonia remained rate limiting. No spectrally detectable intermediates could be observed during the reaction. The X-ray structure, determined to 3 A resolution, of D303E-MDH showed that the position and coordination geometry of the Ca2+ ion in the active site was altered; the larger Glu303 side chain was coordinated to the Ca2+ ion and also hydrogen bonded to the O5 atom of pyrroloquinoline quinone (PQQ). The properties and structure of the D303E-MDH are consistent with the previous proposal that the reaction in MDH is initiated by proton abstraction involving Asp303, and that the mechanism involves a direct hydride transfer reaction. Mutation of the two adjacent cysteine residues that make up the novel disulfide ring in the active site of MDH led to an inactive enzyme, confirming the essential role of this remarkable ring structure. Mutations of cytochrome c(L), which is the electron acceptor from MDH was used to identify Met109 as the sixth ligand to the heme.

Effects of fluorescence excitation geometry on the accuracy of DNA fragment sizing by flow cytometry.

We report on various excitation geometries used in ultrasensitive flow cytometry that yield a linear relation between the fluorescence intensity measured from individual stained DNA fragments and the lengths of the fragments (in base pairs). This linearity holds for DNA samples that exhibit a wide range of conformations. The variety of DNA conformations leads to a distribution of dipole moment orientations for the dye molecules intercalated into the DNA. It is consequently important to use an excitation geometry such that all dye molecules are detected with similar efficiency. To estimate the conformation and the extent of elongation of the stained fragments in the flow, fluorescence polarization anisotropy and autocorrelation measurements were performed. Significant extension was observed for DNA fragments under the flow conditions frequently used for DNA fragment sizing. Classical calculations of the fluorescence emission collected over a finite solid angle are in agreement with the experimental measurements and have confirmed the relative insensitivity to DNA conformation of an orthogonal excitation geometry. Furthermore, the calculations suggested a modified excitation geometry that has increased our sizing resolution.

Single-molecule detection with total internal reflection excitation: comparing signal-to-background and total signals in different geometries.

Excitation of fluorescence with total internal reflection (TIR) excitation yields very low background scattered light and good signal-to-background contrast. The background and its associated noise can be made low enough to detect single fluorescent molecules under ambient conditions. In this paper, different TIR geometries were compared for excitation and detection of single rhodamine 6G (R6G) molecules at air-silica interfaces and single B-phycoerythrin proteins at water-silica interfaces. Through-objective, objective-coverslip, and prism-based TIR geometries were investigated. The signal-to-background ratio (SBR) and the number of photons detected before photobleaching (Nb) were optimum in different geometries. The greatest image contrast was obtained when using prism-TIR (SBR = 11.5), but the largest number of detected signal photoelectrons was obtained by using through-objective TIR for R6G-air-silica ( = 10(4)). The results were discussed in terms of the TIR field enhancements and the modified dipole emission pattern near a dielectric interface. The SBR and total detected photons are important parameters for designing photon-limited experiments.

Efficient detection of single DNA fragments in flowing sample streams by two-photon fluorescence excitation.

This paper reports the demonstration of efficient single molecule detection in flow cytometry by two-photon fluorescence excitation. We have used two-photon excitation (TPE) to detect single DNA fragments as small as 383 base pairs (bp) labeled with the intercalating dye, POPO-1, at a dye:nucleotide ratio of 1:5. TPE of the dye-DNA complexes was accomplished using a mode-locked, 120 fs pulse width Ti:sapphire laser operating at 810 nm. POPO-1 labeled DNA fragments of 1.1 kilobase pairs (kbp) and larger were sequentially detected in our flow cytometry system with a detection efficiency of nearly 100%. The detection efficiency for the 383 bp DNA fragments was approximately 75%. We also demonstrate the ability to distinguish between different sized DNA fragments in a mixture by their individual fluorescence burst sizes by TPE. These studies indicate that using TPE for single molecule flow cytometry experiments lowers the intensity of the background radiation by approximately an order of magnitude compared to one-photon excitation, due to the large separation between the excitation and emission wavelengths in TPE.

The biochemistry, physiology and genetics of PQQ and PQQ-containing enzymes.

Pyrrolo-quinoline quinone (PQQ) is the non-covalently bound prosthetic group of many quinoproteins catalysing reactions in the periplasm of Gram-negative bacteria. Most of these involve the oxidation of alcohols or aldose sugars. PQQ is formed by fusion of glutamate and tyrosine, but details of the biosynthetic pathway are not known; a polypeptide precursor in the cytoplasm is probably involved, the completed PQQ being transported into the periplasm. In addition to the soluble methanol dehydrogenase of methylotrophs, there are three classes of alcohol dehydrogenases; type I is similar to methanol dehydrogenase; type II is a soluble quinohaemoprotein, having a C-terminal extension containing haem C; type III is similar but it has two additional subunits (one of which is a multihaem cytochrome c), bound in an unusual way to the periplasmic membrane. There are two types of glucose dehydrogenase; one is an atypical soluble quinoprotein which is probably not involved in energy transduction. The more widely distributed glucose dehydrogenases are integral membrane proteins, bound to the membrane by transmembrane helices at the N-terminus. The structures of the catalytic domains of type III alcohol dehydrogenase and membrane glucose dehydrogenase have been modelled successfully on the methanol dehydrogenase structure (determined by X-ray crystallography). Their mechanisms are likely to be similar in many ways and probably always involve a calcium ion (or other divalent cation) at the active site. The electron transport chains involving the soluble alcohol dehydrogenases usually consist only of soluble c-type cytochromes and the appropriate terminal oxidases. The membrane-bound quinohaemoprotein alcohol dehydrogenases pass electrons to membrane ubiquinone which is then oxidized directly by ubiquinol oxidases. The electron acceptor for membrane glucose dehydrogenase is ubiquinone which is subsequently oxidized directly by ubiquinol oxidases or by electron transfer chains involving cytochrome bc1, cytochrome c and cytochrome c oxidases. The function of most of these systems is to produce energy for growth on alcohol or aldose substrates, but there is some debate about the function of glucose dehydrogenases in those bacteria which contain one or more alternative pathways for glucose utilization. Synthesis of the quinoprotein respiratory systems requires production of PQQ, haem and the dehydrogenase subunits, transport of these into the periplasm, and incorporation together with divalent cations, into active quinoproteins and quinohaemoproteins. Six genes required for regulation of synthesis of methanol dehydrogenase have been identified in Methylobacterium, and there is evidence that two, two-component regulatory systems are involved.

Single-molecule identification in flowing sample streams by fluorescence burst size and intraburst fluorescence decay rate.

We report a multiplex technique for identification of single fluorescent molecules in a flowing sample stream by correlated measurement of single-molecule fluorescence burst size and intraburst fluorescence decay rate. These quantities were measured simultaneously for single fluorescent molecules in a flowing sample stream containing a dilute mixture of fluorescent species: Rhodamine 6G and tetramethylrhodamine isothiocyanate. Using a detailed Monte Carlo simulation of our experiment, we calculate single-molecule detection efficiencies and confidence levels for identification of these species and identify major sources of error for single-molecule identification. The technique reported here is applicable to distinguishing between fluorophores with similar spectroscopic properties and requires only a single excitation wavelength and single fluorescence emission detection channel.

New flow cytometric technologies for the 21st century.

The envelope that defines the limits within which flow cytometry was developed is being rapidly expanded. For example: detection sensitivity has been extended to single molecules, the size range of "particle" analysis now extends from DNA fragments to plankton (1,000.+ microns), cell and chromosome sorting rates are being increased dramatically by using inactivation procedures (50,000 per second versus 2,000 per second), rapid kinetic flow cytometry enables real-time analysis of molecular assembly and cell function in the sub-second time domain, the lifetime of a fluorochrome bound to a single cell can be measured with nsec precision, and classical karyotype information (cell to cell heterogeneity) can be determined in a flow based system. These frontiers have greatly expanded the range of new and exciting flow cytometric based biomedical applications. New enabling technologies have provided the means to measure DNA cleavage by the structure-specific nuclease, human Flap Endonuclease (FEN-1), in the 300 msec time frame. Phase sensitive measurements and fluorescence lifetime are proving to be major advances for understanding molecular environments that change with, for example, the process of apoptosis. The ability to detect single fluorescent molecules has been applied to the analysis of DNA fragments obtained from enzymatic digestion of lambda DNA. This technology is being used to rapidly and very accurately size DNA fragments for the human genome project. Optical chromosome selection is a faster, better, less complex approach to chromosome sorting. This method is based on the induction of specific damage to the DNA of selected chromosomes. Lastly, the miniaturization of a single cell fractionator has made it possible to perform single cell flow cytogenetics.

The methanol oxidation genes mxaFJGIR (S) ACKLD in Methylobacterium extorquens.

MxaJ is a protein of unknown function encoded by mxaJ in the mxaFJGI operon. We have constructed a mxaJ mutant of M. extorquens with a deletion which does not affect transcription of downstream genes. It contained cytochrome cL (MxaG), but neither subunit of methanol dehydrogenase (MxaF and MxaI). MxaJ is probably involved in processing this enzyme. We have sequenced the region between mxaFJGI and five other methanol oxidation genes, mxaACKLD; it includes one open reading frame (mxaR) and a possible second open reading frame (mxaS), demonstrating the presence in M. extorquens of the following gene cluster: mxaFJGIR(S) ACKLD.

Reduction of luminescent background in ultrasensitive fluorescence detection by photobleaching.

In luminescence-based ultrasensitive analysis, such as single-molecule detection by flow cytometry, the luminescence background from impurities present in the solvent or reagents can ultimately determine the detection limits. A simple, versatile method for reducing luminescence background is described. The method is based on photobleaching the reagent stream immediately before it enters the detection flow cell. Dramatic reduction (an order of magnitude or more) of both low-level continuous background and single-molecule fluorescence bursts is demonstrated. Application and enhancements of the technique are discussed.

Spatial dependence of the optical collection efficiency in flow cytometry.

The sensitive flow cytometric detection of fluorescent species in liquid sample streams requires efficient collection of light from small [approximately 1 picoliter (pl)] sample volumes. This is often accomplished with high numerical aperture (NA) imaging collection optics used in combination with a spatial filter. A method to measure the spatial variation of the optical collection efficiency within the sample volume, using a submicrometer light source, is described. Measurements of the relative optical collection efficiency are presented for two optical collection systems used in our laboratory for single molecule detection. The measurement are in qualitative agreement with relative optical collection efficiency calculations using a simple geometrical optics model. Absolute measurements of the peak collection efficiencies for the two collection systems are also presented. These absolute collection efficiency measurements are in good quantitative agreement with ideal collection efficiencies calculated using measured transmissions and rated NAs of the collection optics. The utility of this information for the characterization and optimization of sensitive fluorescence detection apparatus is discussed.

Alterations of single molecule fluorescence lifetimes in near-field optical microscopy.

Fluorescence lifetimes of single Rhodamine 6G molecules on silica surfaces were measured with pulsed laser excitation, time-correlated single photon counting, and near-field scanning optical microscopy (NSOM). The fluorescence lifetime varies with the position of a molecule relative to a near-field probe. Qualitative features of lifetime decreases are consistent with molecular excited state quenching effects near metal surfaces. The technique of NSOM provides a means of altering the environment of a single fluorescent molecule and its decay kinetics in a repeatable fashion.

Rapid sizing of individual fluorescently stained DNA fragments by flow cytometry.

Large, fluorescently stained restriction fragments of lambda phage DNA are sized by passing individual fragments through a focused continuous wave laser beam in an ultrasensitive flow cytometer at a rate of 60 fragments per second. The size of the fluorescence burst emitted by each stained DNA fragment, as it passes through the laser beam, is measured in one millisecond. One hundred sixty four seconds of fluorescence burst data allow linear sizing of DNA with an accuracy of better than two percent over a range of 10 to 50 kbp. This corresponds to analyzing less than 1 pg of DNA. Sizing of DNA fragments by this approach is much faster, requires much less DNA, and can potentially analyze large fragments with better resolution and accuracy than with gel-based electrophoresis.

Skin pressure measurements on various mattress surfaces in cancer patients.

Twenty-eight patients with histologically proven carcinoma were studied on two dynamic and six static mattress surfaces to determine which mattress surface would provide the least skin surface pressure at the sacrum, dorsal spine, trochanter and heels. Measurements were taken with an especially designed inflatable bladder, and the mean of the maximum skin surface pressures was determined for the static and dynamic surfaces in the inflated and deflated state. Using less than or equal to 32 mm Hg as the skin surface pressure at which the arteriolarcapillary blood flow is interrupted, we concluded that the mud gel bed generally tended to record the lowest skin surface pressure for all of the sites. Although some of the static surfaces recorded pressures less than or equal to 32 mm Hg at the sacrum and dorsal spine, the deflated dynamic surfaces were superior to the remaining static surfaces in reducing the skin surface pressures.