Tri-mode optical biopsy probe with fluorescence endomicroscopy,Raman spectroscopy,and time-resolved fluorescence spectroscopy

We present an endoscopic probe that combines three distinct optical fibre technologies including: A high-resolution imaging fibre for optical endomicroscopy, a multimode fibre for time-resolved fluorescence spectroscopy, and a hollow-core fibre with multimode signal collection cores for Raman spectroscopy. The three fibers are all enclosed within a 1.2 mm diameter clinical grade catheter with a 1.4 mm end cap. To demonstrate the probe's flexibility we provide data acquired with it in loops of radii down to 2 cm. We then use the probe in an anatomically accurate model of adult human airways, showing that it can be navigated to any part of the distal lung using a commercial bronchoscope. Finally, we present data acquired from fresh ex vivo human lung tissue. Our experiments show that this minimally invasive probe can deliver real-time optical biopsies from within the distal lung - simultaneously acquiring co-located high-resolution endomicroscopy and biochemical spectra.     

Allosteric transition of aspartokinase I-homoserine dehydrogenase I studied by time-resolved fluorescence

The allosteric transition of threonine-sensitive aspartokinase I-homoserine dehydrogenase I from Escherichia coli has been studied by time-resolved fluorescence spectroscopy. Fluorescence decay can be resolved into 2 distinct classes of tryptophan emitters: a fast component, with a lifetime of about 1.5 ns; and a slow component, with a lifetime of about 4.5 ns. The fluorescence properties of the slow component are modified by the allosteric transition. In the T-form of the enzyme stabilized by threonine, the lifetime of the slow component is longer, with a red-shifted spectrum; its accessibility to quenching by acrylamide becomes slightly higher without any decrease of fluorescence anisotropy. These results indicate a change in polarity of the slow component environment. The quaternary structure change associated with the allosteric transition probably involves global movements of structural domains without leading to any local mobility on the nanosecond time-scale. We suggest that the slow component corresponds to the unique tryptophan of the buried kinase domain.     

Cell cycle-dependent binding between Cyclin B1 and Cdk1 revealed by time-resolved fluorescence correlation spectroscopy

Measuring the dynamics with which the regulatory complexes assemble and disassemble is a crucial barrier to our understanding of how the cell cycle is controlled that until now has been difficult to address. This considerable gap in our understanding is due to the difficulty of reconciling biochemical assays with single cell-based techniques, but recent advances in microscopy and gene editing techniques now enable the measurement of the kinetics of protein–protein interaction in living cells. Here, we apply fluorescence correlation spectroscopy and fluorescence cross-correlation spectroscopy to study the dynamics of the cell cycle machinery, beginning with Cyclin B1 and its binding to its partner kinase Cdk1 that together form the major mitotic kinase. Although Cyclin B1 and Cdk1 are known to bind with high affinity, our results reveal that in living cells there is a pool of Cyclin B1 that is not bound to Cdk1. Furthermore, we provide evidence that the affinity of Cyclin B1 for Cdk1 increases during the cell cycle, indicating that the assembly of the complex is a regulated step. Our work lays the groundwork for studying the kinetics of protein complex assembly and disassembly during the cell cycle in living cells.     

Long-lived primary radical pair state detected by time-resolved fluorescence and absorption spectroscopy in an isolated Photosystem two core

A Photosystem two (PS II) core preparation containing the chlorophyll a binding proteins CP 47, CP 43, D1 and D2, and the non-chlorophyll binding cytochrome-b559 and 33 kDA polypeptides, has been isolated from PS II-enriched membranes of peas using the non-ionic detergent heptylthioglucopyranoside and elevated ionic strengths. The primary radical pair state, P680⁺Pheo^-, was studied by time-resolved absorption and fluorescence spectroscopy, under conditions where quinone reduction and water-splitting activities were inhibited. Charge recombination of the primary radical pair in PS II cores was found to have lifetimes of 17.5 ns measured by fluorescence and 21 ns measured by transient decay kinetics under anaerobic conditions. Transient absorption spectroscopy demonstrated that the activity of the particles, based on primary radical pair formation, was in excess of 70% (depending on the choice of kinetic model), while time-resolved fluorescence spectroscopy indicated that the particles were 91% active. These estimates of activity were further supported by steady-state measurements which quantified the amount of photoreducible pheophytin. It is concluded that the PS II core preparation we have isolated is ideal for studying primary radical pair formation and recombination as demonstrated by the correlation of our absorption and fluorescence transient data, which is the first of its kind to be reported in the literature for isolated PS II core complexes from higher plants.Abbreviations CP 43 and CP 47 chlorophyll binding proteins of PS II having apparent molecular weights on SDS-PAGE of 43 kDa and 47 kDa, respectively - D1 and D2 polypeptides PS II reaction centre polypeptides encoded by the psbA and psbD genes, respectively - HPLC high performance liquid chromatography - PS II Photosystem two - SDS-PAGE sodium dodecyl sulphate-polyacrylamide gel electrophoresis - P680 primary electron donor of PS II - Pheo phenophytin a - SPC single photon counting - PBQ phenyl-p-benzoquinone - DPC 1,5-diphenylcarbazide AFRC Photosynthesis Research Group, Department of Biochemistry     

A new fluorescence enhancement solution for Europium-based time-resolved fluoroimmunoassays

A cationic detergent is proposed as suitable insulating agent for the preparation of a fluorescence enhancement solution useful for europium-based time-resolved fluoroimmunoassays. Luminescence from europium ions at concentration as low as 0.5 pmol/l can be detected in solution containing 1.6 mmol/l thenoyltrifluoroacetone, 110.5 μ mol/l Adogen 464 and 0.1% Tween 20, in the presence of 0.5 mol/l NaCl. A competitive TR-FIA for rabbit lgG is described, showing that the new enhancement solution allows a sensitivity comparable to that of the high performance LKB Wallac DELFIA.     

Synchrotron-excited time-resolved fluorescence spectroscopy of adenosine,protonated adenosine and 6N, 6N-dimethyladenosine in aqueous solution at room temperature

The fluorescence behavior of adenosine in neutral solution has been studied by time-resolved spectroscopy using synchrotron excitation and timecorrelated single photon counting, and by decay time measurements. Three emissions have been identified and correlated with three excitation spectra. The assignment of these transitions has been made by comparison with similar measurements on ⁶N, ⁶N-dimethyladenosine (6 DMA), and on adenosine in acid solution (ADO H⁺). It is proposed that two of the transitions of adenosine which correlate with 6DMA originate from coplanar and orthogonal rotational conformers of the amino group. The other transition, correlating with ADO H⁺ may originate either from the ³H-imino tautomer, or from a differently solvated rotational conformer.A partial presentation of this work has been made at the Second Congress of the European Society for Photobiology Padova, Italy, 6–10 September 1987     

Dynamics of unfolded polypeptide chains in crowded environment studied by fluorescence correlation spectroscopy

Proteins have evolved to fold and function within a cellular environment that is characterized by high macromolecular content. The earliest step of protein folding represents intrachain contact formation of amino acid residues within an unfolded polypeptide chain. It has been proposed that macromolecular crowding can have significant effects on rates and equilibria of biomolecular processes. However, the kinetic consequences on intrachain diffusion of polypeptides have not been tested experimentally, yet. Here, we demonstrate that selective fluorescence quenching of the oxazine fluorophore MR121 by the amino acid tryptophan (Trp) in combination with fast fluorescence correlation spectroscopy (FCS) can be used to monitor end-to-end contact formation rates of unfolded polypeptide chains. MR121 and Trp were incorporated at the terminal ends of polypeptides consisting of repetitive units of glycine (G) and serine (S) residues. End-to-end contact formation and dissociation result in "off" and "on" switching of MR121 fluorescence and underlying kinetics can be revealed in FCS experiments with nanosecond time resolution. We revisit previous experimental studies concerning the dependence of end-to-end contact formation rates on polypeptide chain length, showing that kinetics can be described by Gaussian chain theory. We further investigate effects of solvent viscosity and temperature on contact formation rates demonstrating that intrachain diffusion represents a purely diffusive, entropy-controlled process. Finally, we study the influence of macromolecular crowding on polypeptide chain dynamics. The data presented demonstrate that intrachain diffusion is fast in spite of hindered diffusion caused by repulsive interactions with macromolecules. Findings can be explained by effects of excluded volume reducing chain entropy and therefore accelerating the loop search process. Our results suggest that within a cellular environment the early formation of structural elements in unfolded proteins can still proceed quite efficiently in spite of hindered diffusion caused by high macromolecular content.     

Exploring the conformational equilibrium of E. coli thioredoxin reductase: characterization of two catalytically important states by ultrafast flavin fluorescence spectroscopy

The conformational dynamics of wild-type Escherichia coli thioredoxin reductase (TrxR) and the mutant enzyme C138S were studied by ultrafast time-resolved fluorescence of the flavin cofactor in combination with circular dichroism (both in the flavin fingerprint and far-UV regions) and steady-state fluorescence and absorption spectroscopy. The spectroscopic data show two conformational states of the enzyme (named FO and FR), of which the physical characteristics differ considerably. Ultrafast fluorescence lifetime measurements make it possible to distinguish between the two different populations: Dominant picosecond lifetimes of approximately 1 ps (contribution 75%) and 7 ps (8%) are associated with the FO species in TrxR C138S. Long-lived fluorescence with two time constants in the range of 0.2-1 ns (total contribution 17%) originates from enzyme molecules in the FR conformation. The near absence of fast lifetime components in oxidized wild-type TrxR supports the idea of this enzyme being predominantly in the FR conformation. The emission spectrum of the FO conformation is blue-shifted with respect to that of the FR conformation. Because of the large difference in fluorescence characteristics, fluorescence measurements on time scales longer than 100 ps are fully determined by the fraction of enzyme molecules in the FR conformation. Binding of the thiol reagent phenyl mercuric acetate to wild-type enzyme and TrxR C138S stabilizes the enzymes in the FR conformation. Specific binding of the NADPH-analog, AADP(+), to the FR conformation resulted in dynamic fluorescence quenching in support of the multiple quenching sites model. Raising the temperature from 277K-323K resulted in a moderate shift to the FR conformation for TrxR C138S. High concentrations of the cosolvent glycerol triggered the domain rotation from the FO to the FR conformation.     

时间分辨荧光免疫分析技术研究现状及进展

时间分辨荧光免疫分析是一种新型的超微量的免疫标记分析方法,集酶标记免疫分析和放射免疫分析等优点于一身,且无放射性污染等.本文主要介绍了时间分辨荧光免疫分析的原理、优点,螯合剂的种类,以及各种分析技术及其应用现状和进展.     

Inhibition of NADH oxidation by chloramphenicol in the freely moving rat measured by picosecond time-resolved emission spectroscopy

Owing to the lack of methods capable to monitor the energetic processes taking place within small brain regions (i.e. nucleus raphe dorsalis, nRD), the neurotoxicity of various categories of substances, including antibiotics and psycho-active drugs, still remains difficult to evaluate. Using an in vivo picosecond optical spectroscopy imaging method, we report that chloramphenicol (CAP), besides its well-known ability to inhibit the mitochondria protein synthesis, also influences the NADH/NAD+ redox processes of the respiratory chain. At a 200-mg/kg dose, CAP indeed produces a marked increase in the fluorescent signal of the nRD which, according to clear evidence, is likely to be related to the NADH concentration. This effect also implies an efficient inhibition of complex I of the respiratory chain by CAP. It refers to the mechanism through which the adverse effects of the antibiotic may take place. It could explain why paradoxical sleep, a state needing aerobic energy to occur, is suppressed after CAP administration. The present approach constitutes the first attempt to determine by fluorescence methods the effects of substances on deep brain structures of the freely moving animal. It points out that in vivo ultrafast optical methods are innovative and adequate tools for combined neurochemical and behavioural approaches.     

Detection method for quantifying global DNA methylation by fluorescence correlation spectroscopy

A method for quantifying global DNA methylation using fluorescence correlation spectroscopy (FCS) has been established. The single-molecule methylation assay (SMMA) is based on two methodologies. One methodology, FCS, estimates the translational diffusion coefficient of molecules in solution, whereas the other methodology uses the high affinity of methyl-CpG-binding domain protein 2 (MBD2) to bind specifically to methylated DNA. We studied the specific binding rates of fluorescence-labeled MBD2 and methylated DNA from biological samples using the automated FCS system. Using a standard curve with methylated control DNA, we developed the SMMA index to assess the global DNA methylation level of the biological samples. A marked decrease in the SMMA index was observed when human leukemia cell lines (U937 and K562) were cultured with DNA demethylating agents. Our findings clearly indicate the applicability of SMMA as a simple and rapid tool for quantifying global DNA methylation. SMMA may prove useful for genome-wide comparative methylation analyses of malignancies and as an indicator of the demethylation effects of epigenetic drugs.     

Measuring unfolding of proteins in the presence of denaturant using fluorescence correlation spectroscopy

IFABP is a small (15 kDa) protein consisting mostly of antiparallel beta-strands that surround a large cavity into which ligands bind. We have previously used FCS to show that the native protein, labeled with fluorescein, exhibits dynamic fluctuation with a relaxation time of 35 micros. Here we report the use of FCS to study the unfolding of the protein induced by guanidine hydrochloride. Although the application of this technique to measure diffusion coefficients and molecular dynamics is straightforward, the FCS results need to be corrected for both viscosity and refractive index changes as the guanidine hydrochloride concentration increases. We present here a detailed study of the effects of viscosity and refractive index of guanidine hydrochloride solutions to calibrate FCS data. After correction, the increase in the diffusion time of IFABP corresponds well with the unfolding transition monitored by far ultraviolet circular dichroism. We also show that the magnitude of the 35 micros phase, reflecting the conformational fluctuation in the native state, decreases sharply as the concentration of denaturant increases and the protein unfolds. Although FCS experiments indicate that the unfolded state at pH 2 is rather compact and native-like, the radius in the presence of guanidine hydrochloride falls well within the range expected for a random coil.     

Steady state and time resolved effects of guanidine hydrochloride on the structure of Humicola lanuginosa lipase revealed by fluorescence spectroscopy

Effects of guanidine hydrochloride (GdnHCl) on the structure and dynamics of wild-type Humicola lanuginosa lipase (HLL) and its two mutants were studied. The latter were S146A (with the active site Ser replaced by Ala) and the single Trp mutant W89m, with substitutions W117F, W221H, and W260H. Steady-state, stopped-flow, and time-resolved laser-induced fluorescence spectroscopy were carried out as a function of [GdnHCl]. The maximum emission wavelength and fluorescence lifetimes revealed the microenvironment of the tryptophan(s) in these lipases to become more polar upon increasing [GdnHCl]. However, significant extent of tertiary structure in GdnHCl is suggested by the observation that both wild-type HLL and W89m remain catalytically active at rather high GdnHCl concentrations of >6 and 4.0 M, respectively. Changes in steady-state emission anisotropy, as well as variation in rotational correlation times and residual anisotropy values, demonstrate that upon increasing [GdnHCl] the structure of the lipases became more loose, with increasing amplitude of structural fluctuations. Finally, intermediate states in the course of exposure of the proteins to GdnHCl were revealed by stopped-flow fluorescence measurements.     

Probing receptor-translocator interactions in the oligopeptide ABC transporter by fluorescence correlation spectroscopy

The oligopeptide transporter Opp is a five-component ABC uptake system. The extracytoplasmic lipid-anchored substrate-binding protein (or receptor) OppA delivers peptides to an integral membrane complex OppBCDF (or translocator), where, on ATP binding and hydrolysis, translocation across the membrane takes place. OppA and OppBCDF were labeled with fluorescent probes, reconstituted into giant unilamellar vesicles, and the receptor-translocator interactions were investigated by fluorescence correlation spectroscopy. Lateral mobility of OppA was reduced on incorporation of OppBCDF into giant unilamellar vesicles, and decreased even further on the addition of peptide. Fluorescence cross-correlation measurements revealed that OppBCDF distinguished liganded from unliganded OppA, binding only the former. Addition of ATP or its nonhydrolyzable analog AMP-PNP resulted in release of OppA from OppBCDF. In vanadate-trapped “transition state” conditions, OppA also was not bound by OppBCDF. A model is presented in which ATP-binding to OppDF results in donation of peptide to OppBC and simultaneous release of OppA. ATP-hydrolysis would complete the peptide translocation and reset the transporter for another catalytic cycle. Implications in terms of a general transport mechanism for ABC importers and exporters are discussed.     

Development of high-throughput spermidine synthase activity assay using homogeneous time-resolved fluorescence

Spermidine synthase (SPDS) catalyzes transfer of the propylamine group from decarboxylated S-adenosylmethionine (dcSAM) to putrescine to yield methylthioadenosine (MTA) and spermidine. SPDS plays a regulatory role in cell proliferation and differentiation. This article describes the development of a high-throughput SPDS activity assay using homogeneous time-resolved fluorescence (HTRF) based on energy transfer from europium cryptate as a donor to crosslinked allophycocyanin (XL665) as an acceptor. First a highly specific anti-MTA monoclonal antibody, MTA-7H8, was generated, and then a competitive immunoassay for MTA determination was developed using europium cryptate-labeled MTA-7H8 and XL665-labeled MTA. In our homogeneous immunoassay, the percentage molar cross-reactivity of dcSAM with MTA-7H8 was 0.01% and the detection limit of MTA was 2.6 pmol/well. Our HTRF assay uses only one assay plate in which both enzyme reaction and MTA determination can be done successively. Therefore, our method can enable automatic screening of SPDS inhibitors from large numbers of samples.     

Thermally stable harpin,HrpZPss is sensitive to chemical denaturants: Probing tryptophan environment,chemical and thermal unfolding by fluorescence spectroscopy

Harpins – a group of proteins that elicit hypersensitive response (HR) in non-host plants – are secreted by certain Gram-negative plant pathogenic bacteria upon interaction with the plant. In the present study, the microenvironment and solvent accessibility of the sole tryptophan residue (Trp-167) in harpin HrpZ_Pss, secreted by Pseudomonas syringae pv. syringae, have been characterized by fluorescence spectroscopic studies. Emission λ_max of the native protein at 328 nm indicates that Trp-167 is buried in a hydrophobic region in the interior of the protein matrix. Significant quenching (53%) was seen with the neutral quencher, acrylamide at 0.5 M concentration, whereas quenching by ionic quenchers, I⁻ (∼10%) and Cs⁺ (negligible) was considerably lower. In the presence of 6.0 M guanidine hydrochloride (GdnHCl) the emission λ_max shifted to 350.5 nm, and quenching by both neutral and ionic quenchers increased significantly, suggesting complete exposure of the indole side chain to the aqueous medium. Fluorescence studies on the thermal unfolding of HrpZ_Pss are fully consistent with a complex thermal unfolding process and high thermal stability of this protein, inferred from previous differential scanning calorimetric and dynamic light scattering studies. However, the protein exhibits low resistance to chemical denaturants, with 50% unfolding seen in the presence of 1.77 M GdnHCl or 3.59 M urea. The ratio of m value, determined from linear extrapolation model, for GdnHCl and urea-induced unfolding was 1.8 and suggests the presence of hydrophobic interactions, which could possibly involve leucine zipper-like helical regions on the surface of the protein.     

Single-nucleotide-polymorphism genotyping for whole-genome-amplified samples using automated fluorescence correlation spectroscopy

Whole-genome amplification (WGA) methods were adopted for single-nucleotide-polymorphism (SNP) typing to minimize the amount of genomic DNA that has to be used in typing for thousands of different SNPs in large-scale studies; 5-10 ng of genomic DNA was amplified by a WGA method (improved primer-extension-preamplification-polymerase chain reaction (I-PEP-PCR), degenerated oligonucleotide primer-PCR (DOP-PCR), or multiple displacement amplification (MDA)). Using 1/100 to 1/500 amounts of the whole-genome-amplified products as templates, subsequent analyses were successfully performed. SNPs were genotyped by the sequence-specific primer (SSP)-PCR method followed by fluorescence correlation spectroscopy (FCS). The typing results were evaluated for four different SNPs on tumor necrosis factor receptor 1 and 2 genes (TNFR1 and TNFR2). The genotypes determined by the SSP-FCS method using the WGA products were 100% in concordance with those determined by nucleotide sequencing using genomic DNAs. We have already carried out typing of more than 300 different SNPs and are currently performing 7,500-10,000 typings per day using WGA samples from patients with several common diseases. WGA coupled with FCS allows specific and high-throughput genotyping of thousands of samples for thousands of different SNPs.     

Equilibrium and kinetics of the unfolding and refolding of Escherichia coli Malate Synthase G monitored by circular dichroism and fluorescence spectroscopy

The equilibrium and kinetics studies of an 82 kDa large monomeric Escherichia coli protein Malate Synthase G (MSG) was investigated by far and near-UV CD, intrinsic tryptophan fluorescence and extrinsic fluorescence spectroscopy. We find that despite of its large size, folding is reversible, in vitro. Equilibrium unfolding process of MSG exhibited three-state transition thus, indicating the presence of at least a stable equilibrium intermediate. Thermodynamic parameters suggest this intermediate resembles the unfolded state. However, the equilibrium intermediate exhibits pronounced secondary structure as measured by far-UV CD, partial tertiary structure as delineated by near-UV CD, compactness (m value) and exposed hydrophobic surface area as assessed by ANS binding, typically depicting a molten globule state. The stopped-flow kinetic data provide clear evidence for the presence of a burst phase during the refolding pathway due to the formation of an early Intermediate, within the dead time of the instrument. Refolding from 4 M to various lower concentrations until 0.4 M of GdnHCl follow biphasic kinetics at lower concentrations of GdnHCl (<0.8 M), whereas monophasic kinetics at concentrations above 1.5 M. Also, rollover in the refolding and unfolding limbs of chevron plot verifies the presence of a fast kinetic intermediate at lower concentration of GdnHCl. Based upon the above observations we hereby propose the folding pathway of a large multi-domain protein Malate Synthase G.