Heterogeneous Packing in the Folding/Unfolding Intermediate State of Bitter Gourd Trypsin Inhibitor

The conformation and dynamics of a protein are essential in characterizing the protein folding/unfolding intermediate state. They are closely involved in the packing and site-specific interactions of peptide elements to build and stabilize the tertiary structure of the protein. In this study, it was confirmed that trypsin inhibitor obtained from seeds of bitter gourd (BGTI) adopted a peculiar but plausible conformation and dynamics in the unfolding intermediate state. The fluorescence spectrum of one of two tryptophan residues of BGTI, Trp9, shifted to the blue side in the presence of 2–3 M guanidine hydrochloride, although the other, Trp54, did not show this spectral shift. At the same time, the motional freedom of Trp9 revealed by a time-resolved fluorescence study decreased, suggesting that the segmental motion of this residue was more restricted. These results indicate that BGTI takes such a conformation state that the hydrophobic core and loop domains arranging Trp9 and Trp54 respectively are heterogeneously packed in the unfolding intermediate state.     

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.     

Unfolding of hirudin characterized by the composition of denatured scrambled isomers

The native core structure of hirudin, a thrombin specific inhibitor, contains 24 hydrogen bonds, two stretches of -sheet and three disulfide bonds. Hirudin unfolds in the presence of denaturant and thiol catalyst by shuffling its native disulfide bonds and converting to scrambled structures that consist of 11 identified isomers. The composition of scrambled isomers, which characterizes the structure of denatured hirudin, varies as a function of denaturing conditions. The unfolding pathway of hirudin has been constructed by quantitative analysis of scrambled isomers unfolded under increasing concentrations of various denaturants. The results demonstrate a progressive expansion of the polypeptide chain and the existence of a structurally defined stable intermediate along the pathway of unfolding.     

The disulfide structure of denatured epidermal growth factor: preparation of scrambled disulfide isomers

The conformational stability of human epidermal growth factor (EGF) and the structure of denatured EGF were investigated using the technique of disulfide scrambling. Under denaturing conditions and in the presence of a thiol catalyst, the native EGF denatures by shuffling its three native disulfide bonds and converts to a mixture of scrambled isomers. Analysis by HPLC reveals that the denatured EGF is composed of about 10 fractions of scrambled isomers. The heterogeneity varies under different denaturing conditions, with the heat-denatured samples exhibiting the highest degree of heterogeneity. The disulfide structures of eight major scrambled isomers of EGF were determined. The most predominant isomer adopts the bead-form structure with disulfide bonds bridged by three pairs of neighboring cysteines: Cys⁶-Cys¹⁴, Cys²⁰-Cys³¹, and Cys³³-Cys⁴². The denaturation curve of EGF is determined by the relative yield of the scrambled and native species of EGF. EGF is a highly stable molecule and can be effectively denatured only by guanidine chloride at a concentration of greater than 4–5 M. At 8 M urea, less than 16% of the native EGF was denatured. The unusual conformational stability of EGF was compared with that of eight different disulfide proteins that were similarly characterized by the method of disulfide scrambling.     

现代荧光免疫分析技术应用及其新发展

免疫分析作为一类特殊的试剂分析技术,已经被广泛应用于多个不同领域。作为免疫分析方法家族中的一员,现代荧光免疫分析技术在相关领域里也扮演了重要角色。现代荧光免疫分析技术主要包括荧光偏振免疫分析(FPIA)和时间分辩荧光免疫分析(TRFIA)两种技术。本文从原理角度出发,综述了FPIA和TRFIA近年来在分析领域中的应用,并且阐述了二者的一些最新发展动态。     

Structural differences between the SH3-HOOK-GuK domains of SAP90/PSD-95 and SAP97

The SH3-HOOK-GUK domains of the postsynaptic scaffolding proteins SAP90/PSD-95 and SAP97 are established targets of synaptic plasticity processes in the brain. A crucial molecular mechanism involved is the transition of this domain to different conformational states. We purified the SH3-HOOK-GUK domain of both proteins to examine variations in protein conformation and stability. As monitored by circular dichroism and differential scanning calorimetry, SAP97 (T_m = 64 °C) is significantly more thermal stable than SAP90/PSD-95 (T_m = 52 °C) and follows a bimodal phase transition. GdmCl-induced equilibrium unfolding of both proteins follows the two-state transitions and thus does not involve the accumulation of stable intermediate state(s). Equilibrium unfolding of SAP97 is highly cooperative from a native state to an unfolded state. In contrast, SAP90/PSD-95 follows a non-cooperative transition from native to unfolded states. A highly cooperative unfolding reaction in case of SAP97 indicates that the protein existed initially as a compact, well-folded structure, while the gradual, non-cooperative melting reaction in case of SAP90/PSD-95 indicates that the protein is in comparison more flexible.     

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.     

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.     

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     

Europium as a label in time-resolved immunofluorometric assays

A nonisotopic immunoassay has been developed based on a sensitive detection of europium (III) in water solution using time-resolved fluorometry. The europium label is bound to the antibody with EDTA derivatives, either diazophenyl-EDTA-Eu or isothiocyanatophenyl-EDTA-Eu. After the immunometric assay has been completed the europium is preferably dissociated from the antibody at low pH and measured by time-resolved fluorescence in a micellar solution containing Triton X-100, β-diketone, and a Lewis base. The detergent solubilizes the chelating compounds in the solution and excludes water from the fluorescent ligand-europium complex. Europium concentrations as low as 5·10^?14m were measured using a 1-s counting time. The sensitivity of the immunoassay of rabbit IgG used as a model system was 25 pg/ml (6 pg/assay).     

The unfolding intermediate state of calf intestinal alkaline phosphatase during denaturation in guanidine solutions

The equilibrium unfolding of calf intestinal alkaline phosphatase in guanidinium chloride (GdmCl) solutions was studied by following the fluorescence and ultraviolet difference spectra. At low concentrations of GdmCl (< 1.6 M), the fluorescence intensity decreased with a slight red shift of the emission maximum from 332 nm to 344 nm. An unfolding intermediate state was observed at a broad concentration range of GdmCl as a denaturant (between 1.6 and 2.6 M). This intermediate was characterized by increased fluorescence emission intensity, ultraviolet difference absorption at 236 nm and 260 nm, as well as increased binding to the protein and red shift of the fluorescence probe 1-anilinonaphthalene-8-sulfonic acid.     

Visualization of excitation energy transfer processes in plants and algae

Development of the time-resolved fluorescence spectroscopy in the pico-second time range and its application to the energy transfer processes in many photosynthetic organisms is reviewed here. This method enabled visualization of energy transfer processes by three-dimensional expression of fluorescence spectra and discrimination of kinetic components and spectral components. The second generation of the ultrafast fluorescence spectroscopy is the femto-second (fs) fluorescence up-conversion, and this has enabled analyses of the transfer processes from carotenoids to chlorophylls with a resolution of less than 100 fs. For future progress, a further development of the spectroscopy is indispensable as well as structural data at atomic resolution. This revised version was published online in June 2006 with corrections to the Cover Date.     

A model for the 77 K excited state dynamics in Chlamydomonas reinhardtii in state 1 and state 2

The regulatory mechanism of state transitions was studied in Chlamydomonas reinhardtii (C.r.) wild type (WT) as well as mutant strains deficient in the photosystem I (PSI) or the photosystem II (PSII) core. Time-resolved fluorescence measurements were obtained on instantly frozen cells incubated beforehand in the dark in aerobic or anaerobic conditions which leads to state 1 (S1) or state 2 (S2). WT data contains information on the light-harvesting complex (LHC) connected to PSI and PSII. The mutants' data contain information on either LHCII-LHCI-PSI or LHCII-PSII, plus information on LHC antennas devoid of a PS core. In a simultaneous analysis of the data from all strains under S1 or S2 conditions a unified model for the excited state dynamics at 77 K was created. This yielded the completely resolved LHCII-LHCI-PSI and LHCII-PSII dynamics and quantified the state transitions. In WT cells the fraction of light absorbed by LHCII connected to PSII decreases from 45% in S1 to 29% in S2, while it increases from 0% to 16% for LHCII connected to PSI. Thus (16/45 =) 36% of all LHCII is involved in the state transition. In the mutant strains deficient in the PSI core, the red most species peaking at 716 nm disappears completely, indicating that this far red Chl pigment is located in the PSI core. In the mutant strain deficient in the PSII core, red shifted species with maxima at 684 and 686 nm appear in the LHCII antenna. LHCII-684 is quenched and decays with a rate of (310 ps)^? 1.