The internal motion of F-actin in the time range from 10(-6) to 10(-3) second has been explored by measuring the transient absorption anisotropy of eosin-labeled F-actin using laser flash photolysis. The transient absorption anisotropy of eosin-F-actin at 20 degrees C has a component that decays in the submicrosecond time scale to an anisotropy of about 0.3. This anisotropy then decays with a relaxation time of about 450 microseconds to a residual anisotropy of about 0.1 after 2 ms. When the concentration of eosin-F-actin was varied in the range from 7 to 28 microM, the transient absorption anisotropy curves obtained were almost indistinguishable from each other. These results show that the anisotropy decay arises from internal motion of eosin-F-actin. Analysis of the transient absorption anisotropy curves indicates that the internal motion detected by the decay in anisotropy is primarily a twisting of actin protomers in the F-actin helix; bending of the actin filament makes a minor contribution only to the measured decay. The torsional rigidity calculated from the transient absorption anisotropy is 0.2 X 10(-17) dyn cm2 at 20 degrees C, which is about an order of magnitude smaller than the flexural rigidity determined from previous studies. Thus, we conclude that F-actin is more flexible in twisting than in bending. The calculated root-mean-square fluctuation of the torsional angle between adjacent actin protomers in the actin helix is about 4 degrees at 20 degrees C. We also found that the torsional rigidity is approximately constant in the temperature range from 5 to approximately 35 degrees C, and that the binding of phalloidin does not appreciably affect the torsional motion of F-actin. 相似文献
The article briefly reports the fundamental scientific principles and landmarks in the field of luminescence and further enlightens the importance of persistent phosphor that is now widely used in luminous paints. Its main focus is on phosphorescence that makes use of lanthanides that have gained paramount importance in various cross-sections of luminescent applications. Both inorganic and organic afterglow materials, synthesis and characterization along with skilled researchers' essential updates on emerging trends and efforts are elucidated at length. It exclusively reviews the red/green/blue organic/inorganic/hybrid phosphorescent materials and the latest advances in the development of novel long afterglow materials that can accelerate the green technology in the world of luminescence. 相似文献
Fluorescence and phosphorescence emission spectroscopy were employed to study the interaction of Escherichia coli purine nucleoside phosphorylase (PNP) with its specific inhibitor, formycin A (FA), a close structural analogue of adenosine (natural substrate), in the absence and presence of phosphate (Pi, substrate). Formation of enzyme–FA complexes led to marked quenching of enzyme tyrosine intrinsic fluorescence and phosphorescence, with concomitant increases in fluorescence and phosphorescence of FA. Fluorescence resonance energy transfer from the protein Tyr160 residue to the FA base moiety was identified as a major mechanism of protein fluorescence quenching, increased by addition of Pi. The effects of enzyme–FA interactions on the nucleoside excitation and emission spectra for fluorescence and phosphorescence revealed shifts in the tautomeric equilibrium of the bound FA, i.e. from the N(1)–H tautomer (predominant in solution) to the N(2)–H form, enhanced by the presence of Pi. The latter was confirmed by enzyme–ligand dissociation constant (Kd) values of 5.9±0.4 and 2.1±0.3 M in the absence and presence of Pi, respectively. Addition of glycerol (80%, v/v) led to a lower enzyme affinity (Kd70 M), without changes in binding stoichiometry. Enzyme–FA complex formation led to a higher increase of the fluorescence than the phosphorescence band of the ligand, consistent with the fact that the N(2)–H tautomer is characterized by a weaker phosphorescence than the N(1)–H tautomeric form. These results show, for the first time, the application of phosphorescence spectroscopy to the identification of the tautomeric form of the inhibitor bound by the enzyme.Abbreviations Ado
adenosine
- FA
formycin A [3-(-d-ribofuranosyl)-7-aminopyrazolo[4,3-d]pyrimidine]
- FB
formycin B
- FRET
fluorescence resonance energy transfer
- Guo
guanosine
- Hepes
N-(2-hydroxyethyl)piperazine-N-(2-ethanesulfonic acid)
- Ino
inosine
- m1FA
N(1)-methylformycin A
- m2FA
N(2)-methylformycin A
- m4FA
N(4)-methylformycin A
- m6FA
N(6)-methylformycin A
- m7Guo
N(7)-methylguanosine
- Pi
orthophosphate
- PNP
purine nucleoside phosphorylase
- Xao
xanthosine 相似文献
Oxygen delivery and metabolism represent key factors for organ function in health and disease. We describe the optical key characteristics of a technique to comprehensively measure oxygen tension (PO2) in myocardium, using oxygen‐dependent quenching of phosphorescence and delayed fluorescence of porphyrins, by means of Monte Carlo simulations and ex vivo experiments. Oxyphor G2 (microvascular PO2) was excited at 442 nm and 632 nm and protoporphyrin IX (mitochondrial PO2) at 510 nm. This resulted in catchment depths of 161 (86) µm, 350 (307) µm and 262 (255) µm respectively, as estimated by Monte Carlo simulations and ex vivo experiments (brackets). The feasibility to detect changes in oxygenation within separate anatomical compartments is demonstrated in rat heart in vivo.
Quantum dot (QD) nanohybrids provide an effective route to explore the new properties of materials and are increasingly used as highly valuable sensitive (bio) chemical probes. Interestingly, the room-temperature phosphorescence (RTP) of 3-mercaptopropionic acid (MPA)-capped Mn-doped ZnS QDs could be remarkably enhanced by the addition of protamine. Based on the above finding, a simple, sensitive, and selective method for rapid detection of protamine was successfully designed. With this method, protamine as a cationic peptide interacts electrostatically with MPA-capped Mn-doped ZnS QDs to form MPA-capped Mn-doped ZnS QD/protamine complexes, which leads to the aggregation of QDs and enhances the RTP intensity. Under the optimized conditions, the RTP intensity change was linearly proportional to the concentration of protamine in the range 0.2–3.0 μg ml−1, and the limit of detection was 0.14 μg ml−1. The proposed method was successfully applied to detect protamine in protamine sulfate injection and human serum samples with satisfactory results, and the recovery ranged from 96.5 to 105.6%. 相似文献
This article reports the kinetic determination of 6-methoxy-2-naphthylacetic acid (6-MNA), the major metabolite of nabumetone, from micelle-stabilized room temperature phosphorescence (MS-RTP) measurements made by using the stopped-flow mixing technique. This methodology allows one to determine analytes in complex matrices without the need for a tedious separation process. It also shortens analysis times substantially. The proposed method uses simplex methodology to optimize the chemical and instrumental variables affecting the phosphorescence. It was applied to the determination of 6-MNA in human urine. The maximum phosphorescence signal is obtained within only 10 s after the sample is prepared. The maximum slope of the kinetic curve, which corresponds to the maximum rate of the phosphorescence development, is measured at lambda(ex)=273 nm and lambda(em)=516 nm. Least-squares regression was used to fit experimental data, and the detection limit, repeatability, and standard deviation for replicate samples were determined. 相似文献
Fluorescence and phosphorescence measurements have been carried out on single-p tryptophan (Trp 43 or Trp 75)-containing mutants of Tet repressor (Tet R). Tet R containing Trp 43, the residue localized in the DNA recognition helix of the repressor, has been used to observe the binding of Tet R to two 20-bp DNA sequences of tet O1 and tet O2 operators. Binding of Tet R to tet O1 operator leads to a 78% decrease of the repressor fluorescence intensity, with an accompanying 20-nm blue shift of its fluorescence emission maximum to 330 nm. Upon binding of Tet R to tet O2 operator, the Trp 43 fluorescence intensity is quenched by 60%, and a 10-nm shift of its emission maximum to 340 nm occurs. Solute fluorescence quenching studies, using acrylamide, performed at low ionic strength indicate that in both the complex of Tet R with the O1 and that with the O2 operator, Trp 43 is moderately buried, as indicated by a bimolecular rate quenching constant of about 1.8 × 109 M–1 sec–1. In contrast to the Tet R–tet O2 complex, the Stern–Volmer acrylamide quenching constant Ksv of the complex with tet O1 operator changes from 7.5 M–1 at 5 mM NaCl to 22 M–1 at 200 mM NaCl, indicating different exposures of Trp 43 in the two complexes in solutions of higher ionic strength. Phosphorescence studies showed a 0–0 vibronic transition at 408 and 403 nm for Trp 43 and Trp 75, respectively. Upon binding of Tet R to the tet operators, we observed red shifts of 0–0 vibronic bands of Trp 43 to 413 and 412 nm for tet O1 and tet O2 operator, respectively, and the phosphorescence triplet lifetime of Trp 43 at 75 K was quenched from 6.0–5.5 to 3.5–3.3 sec. The thermal phosphorescence quenching profile ranged from –200°C to –20°C, and differed drastically for the two complexes, suggesting different dynamics of the microenvironment of the Trp 43 residue. The luminescence data for Trp 43 of Tet R suggest that the recognition helix of Tet R interacts in different fashions with the tet O1 and tet O2 operators. 相似文献
The traditional paradigm of tissue engineering of regenerating in vitro tissue or organs, through the combination of an artificial matrix and a cellular population has progressively changed direction. The most recent concept is the realization of a fully functional biohybrid, where both, the artificial and the biotic phase, concur in the formation of the novel organic matter. In this direction, interest is growing in approaches taking advantage of the control at micro- and nano-scale of cell material interaction based on the realization of elementary tassels of cells and materials which constitute the beginning point for the expansion of 3D more complex structures. Since a spontaneous assembly of all these components is expected, however, it becomes more fundamental than ever to define the features influencing cellular behavior, either they were material functional properties, or material architecture. In this work, it has been investigated the direct effect of electrospun fiber sizes on oxygen metabolism of h-MSC cells, when any other culture parameter was kept constant. To this aim, thin PCL electrospun membranes, with micro- and nano-scale texturing, were layered between two collagen slices up to create a sandwich structure (μC-PCL-C and nC-PCL-C). Cells were seeded on membranes, and the oxygen consumption was determined by a phosphorescence quenching technique. Results indicate a strong effect of the architecture of scaffolds on cell metabolism, also revealed by the increasing of HIF1-α gene expression in nC-PCL-C. These findings offer new insights into the role of materials in specific cell activities, also implying the existence of very interesting criteria for the control of tissue growth through the tuning of scaffold architecture. 相似文献