Conformational states in denaturants of cytochrome c and horseradish peroxidases examined by fluorescence and circular dichroism

Steady-state fluorescence and circular dichroism (CD) were used to examine the unfolding in denaturants of recombinant cytochrome c peroxidase [CCP(MI)] and horseradish peroxidase (HRP) in their ferric forms. CCP(MI) unfolds in urea and in guanidine hydrochloride (GdHCl) at pH 7.0, while HRP loses its secondary structure only in the presence of GdHCl. CCP(MI) unfolds in urea by two distinct steps as monitored by fluorescence, but the loss of its secondary structure as monitored by UV/CD occurs in a single step between 3.4 and 5 M urea and 1.5 and 2.5 M GdHCl. The localized changes detected by fluorescence involve the CCP(MI) heme cavity since the Soret maximum red-shifts from 408 to 416 nm, and the heme CD changes examined in urea are biphasic. The polypeptide of HRP also loses secondary structure in a single step between 1.2 and 2.7 M GdHCl as monitored by UV/CD, and a fluorescence-monitored transition involving conformational change in the Trp117-containing loop occurs above 4 M GdHCl. Free energies of denaturation extrapolated to 0 M denaturant (delta Gd,aq) of approximately 6 and approximately 4 kcal/mol were calculated for CCP(MI) and HRP, respectively, from the UV/CD data. The refolding mechanisms of the two peroxidases differ since heme capture in CCP(MI) is synchronous with refolding while apoHRP captures heme after refolding. Thus, the denatured form of apoHRP does not recognize heme and has to correctly refold prior to heme capture. The half-life for unfolding of native HRP in 6 M GdHCl is slow (519 s) compared to that for CCP(MI) (14.3 s), indicating that HRP is kinetically much more stable than CCP(MI). Treatment with EDTA and DTT greatly destabilizes HRP, and unfolding in 4 M GdHCl occurs with t1/2 = 0.42 s.     

Interactive intermediates are formed during the urea unfolding of rhodanese

Structural transitions have been studied on the pathway for urea denaturation of rhodanese. Unlike guanidinium hydrochloride, urea gives no visible precipitation. Increasing urea concentrations cause a transition in which the enzyme activity is completely lost by 4.5 M urea, and there is a shift of the intrinsic fluorescence maximum from 335 nm for the native enzyme to 350 nm. There is a maximum exposure of organized hydrophobic surfaces at 4.5 M urea as reported by the fluorescence of 1,1'-bi(4-anilino)naphthalene-5,5'-disulfonic acid. Above 4.5 M urea, this probe reports the progressive loss of organized hydrophobic surfaces. The polarization of the intrinsic fluorescence falls with increasing urea concentrations in a complex transition showing that rhodanese flexibility increases in at least two phases. Rhodanese becomes increasingly susceptible to digestion by subtilisin between 3.5 and 4.5 M urea, giving rise to large fragments. At urea concentrations > 5 M, rhodanese is completely digested. There is a small increase in the rate of sulfhydryl accessibility between 3.5 and 4.5 M urea, but there is a large increase in the sulfhydryl accessibility above 4.5 M urea. Dimethyl suberimidate cross-linking shows the presence of associated species in 3-5 M urea, but there are few cross-linkable species at lower or higher urea concentrations. These results are consistent with a model in which urea unfolding of rhodanese is associated with the initial production of a species having organized regions of structure with exposed hydrophobic surfaces separated by flexible elements.     

Fluorescence quenching and time-resolved fluorescence studies on Momordica charantia (bitter gourd) seed lectin

Chemical modification studies implicated tryptophan (Trp) residues in the sugar binding activity of Momordica charantia lectin (MCL) [Mazumdar, T., Gaur, N. & Surolia, A. (1981) Eur. J. Biochem. 113, 463-470]. In the present study, the accessibility and environment of Trp residues in MCL were investigated by intrinsic fluorescence quenching and time-resolved fluorescence. The emission lamda max of native MCL in the absence as well as in the presence of 0.1 M lactose was around 335 nm, which shifted to 365 nm in the presence of 8 M urea, suggesting that the Trp residues which are predominantly buried in the hydrophobic core of the native lectin get exposed to the aqueous environment upon denaturation. At a quencher concentration of 0.5 M, the extent of quenching observed for the native MCL with acrylamide, I- and Cs+ was 46%, 17% and 12%, respectively. In the presence of 0.1 M lactose this quenching was smaller, suggesting that the sugar ligand provides a partial protection to the Trp residues. In time-resolved fluorescence measurements, the decay curves could be fitted well to a biexponential function with the estimated life times 0.92 ns and 4.64 ns for the native protein and 1.15 ns and 5.1 ns in the presence of 0.1 M lactose. All these results are consistent with the involvement of Trp residues in the sugar-binding activity of MCL.     

Fluorescence studies of human semi-beta-hemoglobin assembly

The intrinsic fluorescence properties of human alpha apohemoglobin at protein concentrations from 1 to 5 microM in 0.1 M potassium phosphate buffer, pH 7 or 8 at 5 degrees C were monitored in the absence and presence of a fixed concentration (5 microM) of a fluorescence quenching heme-containing native or Des (146-His, 145-Tyr) beta chain partner. These "reverse quenching" studies revealed that the emission intensity changes observed correlated well with protein concentration and theoretical extent of semi-beta-hemoglobin assembly. Furthermore, the relative quenching efficiencies were calculated to be 0.32, 0.25 and 0.61 for beta (pH 7), beta (pH 8) and Des beta (pH 7) chains, respectively. Thus, heme-mediated quenching was sensitive to the expected pH induced alpha apohemoglobin conformational change and to alteration in beta chain structure. Intramolecular changes induced by carboxylterminal modification (decreased "beta chain self-quenching") appeared to enhance the intermolecular rearrangements (increased "alpha chain partner quenching") seen upon subunit assembly.     

Evidence for at least two native forms of rabbit muscle adenylate kinase in equilibrium in aqueous solution

The time course of 8-anilino-1-naphthalenesulfonic acid (ANS) binding to adenylate kinase (AK) is a biphasic process. The burst phase ends in the dead-time of the stopped-flow apparatus (about 15 ms), whereas the slow phase completes in about 10 min. A Job's plot tests of the binding stoichiometry demonstrates that there is one ANS binding site on AK, but only about 70% of the enzyme can rapidly bind with ANS, indicating that the conformation of native AK molecules is not homogeneous. Further kinetic analysis shows that the effects of ANS and substrates concentration on the burst and slow phase fluorescence building agree well with the multiple native forms mechanism. One form (denoted N1) binds with ANS, whereas the other (denoted N2) does not. ANS binding to N1 results in a burst phase fluorescence increase, followed by the interconversion of N2 to N1, to give the slow phase ANS binding. Under urea denaturation conditions, N2 is easily perturbed by urea and unfolds completely at low denaturant concentrations, whereas N1 is relatively resistant to denaturation and unfolds at higher denaturant concentrations. The existence of multiple native forms in solution may shed some light on the interpretation of the enzyme catalytic mechanism.     

In vitro enzyme activation and folded stability of Pseudomonas aeruginosa exotoxin A and its C-terminal peptide

Pseudomonas aeruginosa exotoxin A(ETA) and its C-terminal, enzymatically active fragment (PE40, 375 residues) were studied by high-performance size-exclusion chromatography, steady-state and stopped-flow fluorescence spectroscopy, and circular dichroism spectroscopy. Both proteins have been overexpressed and purified by high-performance liquid chromatography. The effect of various activation conditions (pH, urea, and DTT) on enzymatic activity was studied. Upon enzymatic activation, structural changes induced within both proteins' structures were monitored, and these changes were correlated with concomitant alterations in the catalytic activity of the proteins. The pH optimum of enzymatic activity for both ETA and PE40 was between 7.0 and 8.0, decreasing to nearly zero at acidic (pH 5.0) and basic (pH 11-12) values. Analysis of the pH titration data revealed the presence of two distinct pKa values which implicate a His residue(s) (likely His-440 and -426) and a Tyr or Lys residue (possibly Tyr-481). The identity and possible role of an active site Lys residue is not known. Additionally, a significant increase in the Stokes radii of both proteins was detected when the pH was lowered from 8.0 to 6.0. The enzymatic activity of PE40 was not affected by urea or DTT, and its Stokes radius decreased monotonically with increasing urea concentration in the presence of DTT. In contrast, the enzymatic activity of ETA peaked when the protein was preincubated with 4.0 M urea, and this coincided with a large transition (increase) in the protein's Stokes radius between 3 and 5 M urea. Furthermore, loss of helical secondary structure of both PE40 and ETA commenced at approximately 2 M urea and progressively diminished at higher denaturant concentrations. The unfolding of both proteins in urea (and DTT) was reversible, and the free energies of unfolding were determined by both circular dichroism and fluorescence spectroscopy and were found to be 13.7 +/- 2.9 and 9.8 +/- 3.4 kJ/mol, respectively, for ETA and were 17.8 +/- 6.8 and 7.5 +/- 3.6 kJ/mol, respectively, for PE40. The refolding rate of PE40 was relatively rapid [t 1/2(1) = 27 s, t 1/2(2) = 624 s], which was in stark contrast to the refolding rate of ETA (t 1/2 = several hours). The relative refolding rates of PE40 and ETA help to explain the mechanism of in vitro enzyme activation and assay.     

水杨基荧光酮-吐温-80-羟丙基-β-环糊精荧光猝灭法测定痕量锌

在羟丙基-β-环糊精（HP-β-CD）和吐温-80（Tween-80）存在下,以NaAc-HAc缓冲溶液为介质,水杨基荧光酮（SAF）为荧光试剂,建立了荧光猝灭法测定痕量锌的新方法。研究了缓冲溶液酸度和加入量、SAF用量、表面活性剂,试剂加入顺序对测定体系的影响,并确定了最佳实验条件。结果表明,于络合物的最大发射波长λem=532 nm处（最大激发波长λex= 370 nm）,Zn2+含量在0.036～4.0 μg/25 mL范围内与荧光猝灭值ΔF呈良好的线性关系,方法检出限为1.42 μg/L。本方法已用于管网水中锌的测定,测得结果与其它方法测得值一致,相对标准偏差(RSD,n=5)为0.42 %。     

Ligand-induced conformational transitions in Escherichia coli phosphofructokinase 2: evidence for an allosteric site for MgATP2-

The binding of ligands to phosphofructokinase 2 (Pfk-2) from Escherichia coli induces changes in the fluorescence emission properties of its single tryptophan residue, Trp88, suggesting that upon binding the protein undergoes a conformational change. This fluorescence probe was used to determine the presence of an allosteric site for MgATP2- in the enzyme. Fructose 6-phosphate (fructose-6-P), the first substrate that binds to the enzyme with an ordered bi-bi mechanism, increases the fluorescence up to 30%. The saturation curve for this compound is hyperbolic with a Kd of 6 microM. The titration of Pfk-2 with MgATP2- causes a quenching of fluorescence of about 30% of its initial value, with a blue shift of 7 nm in the emission maximum. The response is cooperative with a Kd of 80 microM and a Hill coefficient of 2. The interaction of MgATP2- cannot take place at the active site in the absence of fructose-6-P, due to the ordered kinetic mechanism. Addition of compounds that bind to the catalytic site of Pfk-2, such as ATP4- or Mg-AMP-PNP, did not produce significant changes in the fluorescence spectrum of Trp88. However, in the absence of Mg2+, the addition of ATP4- to the enzyme-fructose-6-P complex shows a hyperbolic increase of fluorescence of 8%. Acrylamide steady-state quenching experiments for different enzyme-ligand complexes of Pfk-2, indicate that the tryptophan in the enzyme-MgATP2- complex is exposed to a much smaller extent to the solvent than in the free enzyme or in the enzyme-fructose-6-P complex. The effect of the binding of fructose-6-P or MgATP2- on the polarization fluorescence of the emission of Trp88 in Pfk-2 indicates changes in the local mobility of the Trp88 in both enzyme complexes. The average lifetime for Trp88 in Pfk-2 was found to be unusually large, approximately 7.7 ns, and did not vary significantly with the ligation state of the enzyme, which demonstrates that the quenching or enhancement of fluorescence induced by the ligands is mainly due to the complex formation with Pfk-2. These results demonstrate the presence of an allosteric site for MgATP2- in Pfk-2 from E. coli, responsible for the inhibition of the enzyme activity by this ligand.     

Photoacoustic analysis of proteins: volumetric signals and fluorescence quantum yields

A series of proteins has been examined using time-resolved, pulsed-laser volumetric photoacoustic spectroscopy. Photoacoustic waveforms were collected to measure heat release for calculation of fluorescence quantum yields, and to explore the possibility of photoinduced nonthermal volume changes occurring in these protein samples. The proteins studied were the green fluorescent protein (GFP); intestinal fatty acid binding protein (IFABP), and adipocyte lipid-binding protein (ALBP), each labeled noncovalently with 1-anilinonaphthalene-8-sulfonate (1,8-ANS) and covalently with 6-acryloyl-2-(dimethylamino)naphthalene (acrylodan); and acrylodan-labeled IFABP and ALBP with added oleic acid. Of this group of proteins, only the ALBP labeled with 1,8-ANS showed significant nonthermal volume changes at the beta = 0 temperature (approximately 3.8 degrees C) for the buffer used (10 mM Tris-HCI, pH 7.5) (beta is the thermal cubic volumetric expansion coefficient). For all of the proteins except for acrylodan-labeled IFABP, the fluorescence quantum yields calculated assuming simple energy conservation were anomalously high, i.e., the apparent heat signals were lower than those predicted from independent fluorescence measurements. The consistent anomalies suggest that the low photoacoustic signals may be characteristic of fluorophores buried in proteins, and that photoacoustic signals derive in part from the microenvironment of the absorbing chromophore.     

硒的酶催化荧光猝灭效应研究及其在土壤分析中的应用

在氨性缓冲介质中,痕量硒能阻抑辣根过氧化物酶(HRP)催化H₂O₂氧化L-酪氨酸(L-Tyr)产生荧光的反应。对该体系的荧光猝灭效应进行了探讨,并应用于土壤中痕量硒的测定。在pH 10.0的 NH₃·H₂O-NH₄Cl缓冲溶液中,控制L-Tyr、H₂O₂和HRP的浓度分别为7.50×10^-5 mol/L、1.00×10^-4 mol/L和5.00×10^-7 mol/L,在室温下反应20 min后,于激发波长为314 nm,发射波长为404 nm处测定体系的荧光强度猝灭值(ΔF)。结果表明,硒在质量浓度为0.1～10.0 μg/mL范围内与ΔF呈线性关系,线性回归方程为ΔF=83.123 ρ_{Se }(μg/mL)+0.068 5,相关系数r=0.999 5。方法中硒检出限为0.03 μg/mL。将体系应用于测定富硒土壤样品中痕量硒,测定值与原子吸收光谱法(AAS)相符,相对标准偏差(RSD,n=6)为1.6%～3.2%,加标回收率为98%～103%。     

间苯二酚- O,O′-二乙酸荧光猝灭法测定锑

在OP-10乳化剂存在下, 以NH₃-NH₄Cl缓冲溶液为介质, 间苯二酚- O, O′-二乙酸(m-PA)为荧光试剂, 建立了荧光猝灭法测定锑的方法。考察了缓冲溶液酸度和用量、表面活性剂及其用量、m-PA溶液用量对测定体系的影响, 并确定了最佳实验条件。结果表明, 体系的最大发射波长λ_em=609 nm(最大激发波长λ_ex=302 nm), 锑含量在0.04~0.48 μg/L范围内与荧光猝灭值ΔF呈良好的线性关系, 方法检出限为0.034 5 μg/L。方法用于自来水、泉水和河水样品中锑的测定, 结果与原子吸收光谱法(AAS)一致, 相对标准偏差(RSD, n=6)为3.2%～4.5%。     

Denaturation and association of DNA sequences by certain polypropylene surfaces

UDP-galactose 4-epimerase from yeast Kluyveromyces fragilis is a dimeric molecule of 75 kDa per subunit with one molecule of cofactor NAD per dimer. It undergoes unfolding and complete dissociation in presence of 8 M urea at pH 7.0 by 10 min. It can be functionally reconstituted almost quantitatively in 2 h by dilution with 20 mM sodium phosphate buffer, pH 7 containing 1 mM extraneous NAD under a second order kinetics [Bhattacharyya, D. (1993) Biochemistry 32, 9726-9734]. Denaturation between 10-60 min inversely affects both the rate and maximum recovery of activity upon refolding. Aggregation of this protein has not been observed under these conditions. The time dependent reaction at the unfolded state is independent of pH between 5.4-10.4 but strongly dependent on temperature of denaturation between 0-20 degrees C. Unfolding at 0 degrees C divides the protein largely into two populations-34% of fast folding species following an apparent first order kinetics and 59% of slow folding species following a second order kinetics of reactivation. A very fast folding species of low abundance 3.5-7.5% depending on temperature of denaturation has been identified, which gets active status within the dead time of mixing. Interaction with the active site directed fluorescence probe 1-anilino 8-naphthalene sulfonic acid (1-ANS) and estimation of bound NAD suggest that the catalytic region of this enzyme is not formed in the long term denatured samples. The whole process of reactivation is catalysed by peptidyl prolyl cis-trans isomerase and thus suggests that one or more proline residues stereochemically control the rate limiting step of reactivation.     

Steady state and time-resolved fluorescence study of residual structures in an unfolded form of yeast phosphoglycerate kinase

A previous study performed using steady state fluorescence has revealed the existence of residual structures surrounding the two tryptophan residues in an unfolded form of yeast phosphoglycerate kinase [Garcia, P., et al. (1995) Biochemistry 34, 397-404]. In this paper, we present a more detailed characterization of these residual structures, through the study of two single tryptophan-containing mutants of yPGK, W333F and W308Y. Denaturation experiments have first been performed at low temperatures to assess the nature of the interactions stabilizing these residual structures. On the other hand, the compactness and dynamics of the protein matrix were probed using tryptophan fluorescence quenching by acrylamide at various denaturant concentrations. Taking into consideration the changes in sample viscosity induced by addition of guanidinium chloride made feasible the use of this technique during the denaturation process. These different approaches have shown that the residual structures around tryptophan 308 are mainly stabilized by hydrophobic interactions and are more compact and less fluctuant than the ones surrounding tryptophan 333. Native and denatured yPGK have also been studied by time-resolved fluorescence spectroscopy. In the native protein, tryptophan buried in the core, W333, is mainly associated with a lifetime close to 0.1 ns, whereas tryptophan that is partially accessible to the solvent, W308, has a lifetime close to 0. 5 ns. The time-resolved tryptophan fluorescence emission of wild-type yPGK can be accounted for quantitatively by the summed emissions of its two single tryptophan mutants. The significance of minor long lifetime components is discussed for the two tryptophan residues. This new assignment of fluorescent decay times has allowed for the detection of a folding intermediate in which the environment of tryptophan 333 is modified for denaturant concentrations lower than those for tryptophan 308.     

Spectroscopic properties of Escherichia coli UDP-N-acetylenolpyruvylglucosamine reductase

Purified uridine diphosphate N-acetylenolpyruvylglucosamine reductase (E.C. 1.1.1.158) was analyzed by circular dichroism (CD) and UV-visible spectroscopy to establish the spectral properties of its tightly bound flavin adenine dinucleotide (FAD) cofactor. The polypeptide backbone displayed a single circular dichroic minimum at 208 nm and a single maximum at 193 nm. The CD spectrum of bound flavin exhibited a single major negative Cotton peak at 364 nm and two minor negative Cotton peaks at 464 and 495 nm. The protein was reversibly unfolded in 9.8 M urea and refolded in buffer in the presence of excess FAD. The refolded enzyme incorporated FAD and catalyzed full activity. The bound FAD displayed an absorption maximum at 464 nm with an extinction coefficient of epsilon 464 = 11700 M-1 cm-1. Anaerobic reduction with dithionite was complete at 1 equiv. Anaerobic reduction with nicotinamide adenine dinucleotide phosphate, reduced form (NADPH), also was essentially complete at 1 equiv and produced a long-wavelength absorbance band characteristic of an FAD-pyridine nucleotide charge transfer complex. Photochemical bleaching in the presence of ethylenediaminetetraacetic acid (EDTA) followed exponential kinetics. None of the anaerobic reductive titrations produced a spectral intermediate characteristic of a flavin semiquinone, and all reduced enzyme species could be fully reoxidized by oxygen, with full recovery of catalytic activity. Photochemically reduced enzyme was reoxidized by titration with either NADP+ or uridine diphospho N-acetylglucosamine enolpyruvate (UNAGEP). Reoxidation by NADP+ reached a chemical equilibrium, whereas reoxidation by UNAGEP was stoichiometric. Binding of NADP+ or UNAGEP to the oxidized form of the enzyme produced a dead-end complex that could be titrated by following a 10-nm red shift in the absorption spectrum of the bound FAD. The Kd of NADP+ for oxidized enzyme was 0.7 +/- 0.3 microM and the Kd of UNAGEP was 2.7 +/- 0.3 microM. Solvent deuterium isotope effects on binding were observed for both NADP+ and UNAGEP, depending on the pH. At pH 8.5, the HKd/DKd was 2.2 for NADP+ and 3.9 for UNAGEP. No spectral changes were observed in the presence of a 40-fold excess of uridine diphospho N-acetylmuramic acid (UNAM) either aerobically or anaerobically. These studies have identified spectral signals for five steps in the kinetic mechanism, have indicated that product formation is essentially irreversible, and have indicated that hydrogen bonding or protonation contributes significantly to ground-state complex formation with the physiological substrate.     

Partially folded conformations of inositol monophosphatase endowed with catalytic activity

The stability of porcine brain inositol monophosphatase in the presence of increasing concentrations of urea was investigated at pH 7.5. Exposure of the enzyme to 8 M urea brings about the dissociation of the dimeric species of 58 kDa into monomeric forms as revealed by gel filtration chromatography. Unfolding of the protein by 8 M urea results in a decrease of the ellipticity at 220 nm (20%) together with a perturbation of the near-UV circular dichroism spectrum. Urea-treated inositol monophosphatase binds Co2+ ions with a dissociation constant of 3.3 microM. The enzyme is catalytically competent when assayed with 4-nitrophenyl-phosphate in the presence of the activating ion Co2+ at pH 7.5 in 8 M urea. The apparent activation constant for Co2+ is 2.5 mM. It is postulated that partially folded conformations of monomeric species preserve their catalytic function because the affinity of Co2+ ions for the metal coordination center of the protein is not perturbed by exposure to 8 M urea.     

Unfolding of Plasmodium falciparum triosephosphate isomerase in urea and guanidinium chloride: evidence for a novel disulfide exchange reaction in a covalently cross-linked mutant

The conformational stability of Plasmodium falciparum triosephosphate isomerase (TIMWT) enzyme has been investigated in urea and guanidinium chloride (GdmCl) solutions using circular dichroism, fluorescence, and size-exclusion chromatography. The dimeric enzyme is remarkably stable in urea solutions. It retains considerable secondary, tertiary, and quaternary structure even in 8 M urea. In contrast, the unfolding transition is complete by 2.4 M GdmCl. Although the secondary as well as the tertiary interactions melt before the perturbation of the quaternary structure, these studies imply that the dissociation of the dimer into monomers ultimately leads to the collapse of the structure, suggesting that the interfacial interactions play a major role in determining multimeric protein stability. The Cm(urea)/Cm(GdmCl) ratio (where Cm is the concentration of the denaturant required at the transition midpoint) is unusually high for triosephosphate isomerase as compared to other monomeric and dimeric proteins. A disulfide cross-linked mutant protein (Y74C) engineered to form two disulfide cross-links across the interface (13-74') and (13'-74) is dramatically destablized in urea. The unfolding transition is complete by 6 M urea and involves a novel mechanism of dimer dissociation through intramolecular thiol-disulfide exchange.     

Protein secretion in suspensions of isolated rat hepatocytes: no influence of acute ethanol administration

The effect of ethanol on the secretion of proteins was studied in hepatocytes isolated from 24-h fasted rats and from fed rats. Hepatocytes were isolated after collagenase disruption of the liver and incubated in a standard medium containing amino acids, bovine albumin, glucose, penicillin and streptomycin in HEPES buffer. Cell viability was determined by urea production and trypan blue exclusion. When studying protein export, a model had to be chosen in which the labeling is accomplished before the addition of the test agents. Cells were incubated with [3H]valine for 2.5 and 7.5 min followed by a 15-mM valine chase and the incubates were adjusted to final concentrations of ethanol of 50 mM, 100 mM, colchicine 5-50 microM or cycloheximide 18 microM. Cells and media were harvested at various times, and counts incorporated into medium and cell protein were determined. Cycloheximide inhibited protein synthesis by 99%, decreased protein secretion by 10-20%, but did not further inihibit protein labeling when given after the chase confirming the chase's effectiveness. Colchicine inhibited protein release by 27-54% depending on the dose. With control cells labeled protein and specifically albumin appeared in the medium 20 min from the start of the pulse and this release of protein was not inhibited by 50 mM or 100 mM ethanol incubated with cells from the same animal whether the donor has been fed or fasted. The values for the ethanol-treated cells ranged from 94.0 to 113% of the control values from 30 to 120 min after the addition of the pulse. Lactate levels were markedly elevated, and urea synthesis decreased in the presence of either 50 mM EtOH or 100 mM EtOH. Thus using a method that can distinguish the effect of ethanol on synthesis from secretion, it is concluded that acute exposure to EtOH does not interfere with protein secretion.     

Time-resolved fluorescence studies of dityrosine in the outer layer of intact yeast ascospores

The (time-resolved) fluorescence properties of dityrosine in the outermost layer of the spore wall of Saccharomyces cerevisiae were investigated. Steady-state spectra revealed an emission maximum at 404 nm and a corresponding excitation maximum at 326 nm. The relative fluorescence quantum yield decreased with increasing proton concentration. The fluorescence decay of yeast spores was found to be nonexponential and differed pronouncedly from that of unbound dityrosine in water. Analysis of the spore decay recorded at lambda ex = 323 nm and lambda em = 404 nm by an exponential series (ESM) algorithm revealed a bimodal lifetime distribution with maxima centered at tau 1C = 0.5 ns and tau 2C = 2.6 ns. The relative amplitudes of the two distributions are shown to depend on the emission wavelength, indicating contributions from spectrally different dityrosine chromophores. On quenching the spore fluorescence with acrylamide, a downward curvature of the Stern-Volmer plot was obtained. A multitude of chromophores more or less shielded from solvent in the spore wall is proposed to account for the nonlinear quenching of the total spore fluorescence. Analysis of the fluorescence anisotropy decay revealed two rotational correlation times (phi 1 = 0.9 ns and phi 2 = 30.6 ns) or a bimodal distribution of rotational correlation times (centers at 0.7 ns and 40 ns) when the data were analyzed by the maximum entropy method (MEM). We present a model that accounts for the differences between unbound (aqueous) and bound (incorporated in the spore wall) dityrosine fluorescence. The main feature of the photophysical model for yeast spores is the presence of at least two species of dityrosine chromophores differing in their chemical environments. A hypothetical photobiological role of these fluorophores in the spore wall is discussed: the protection of the spore genome from mutagenic UV light.     

Confocal scanning microspectrofluorometry reveals specific anthracyline accumulation in cytoplasmic organelles of multidrug-resistant cancer cells

We used confocal microspectrofluorometry to investigate intracellular distribution of pirarubicin or THP-DOX in parental K562, CEM, and LR73 tumor cells and their corresponding multidrug-resistant (MDR) strains. Each spectrum of a recorded image was considered as a combination of cell autofluorescence and fluorescence of the drug. In the cytoplasm of parental K562, CEM, and LR73 cells, THP-DOX fluorescence emission profile was similar to that of free drug in aqueous buffer. The (I550nm/I600nm) ratio was 0. 50 +/- 0.1. However, in the cytoplasm of resistant cells the 550-nm band profile was modified. The I550nm/I600nm ratio was 0.85 +/- 0.2 in MDR K562 cells, which is significantly different from the ratio in sensitive cells (p<0.01). This appeared first to correspond to accumulation and self-oligomerization of THP-DOX in cytoplasmic organelles of MDR cells. Transfection of LR73 cells with the mdr1 gene conferred this characteristic on the resistant LR73R cells. Bodipy-ceramide, a trans-Golgi probe, was co-localized with the typical fluorescence emission peak at 550 nm observed in the cytoplasm of MDR cells. This organelle has been shown to be more acidic in MDR cells. Moreover, this specific pattern was similar to that observed when anthracycline is complexed with sphingomyelin. The typical fluorescence emission peak at 550 nm decreased in MDR cells incubated simultaneously in the presence of the drug and quinine, verapamil, or S9788. Growth inhibitory effect and nuclear accumulation of THP-DOX data obtained on LR73R and LR73D cell lines showed that only during reversion of resistance by verapamil and S9788 was an increase of nuclear THP-DOX accumulation observed. Our data suggest that characteristics of molecular environment, such as higher pH gradient or lipid structures, would be potential mechanisms of multidrug-resistance via the sequestration of anthracyclines.     

Fluorescence quenching by chlorophyll cations in photosystem II

Although fluorescence is widely used to study photosynthetic systems, the mechanisms that affect the fluorescence in photosystem II (PSII) are not completely understood. The aim of this study is to define the low-temperature steady-state fluorescence quenching of redox-active centers that function on the electron donor side of PSII. The redox states of the electron donors and acceptors were systematically varied by using a combination of pretreatments and illumination to produce and trap, at low temperature, a specific charge-separated state. Electron paramagnetic resonance spectroscopy and fluorescence intensity measurements were carried out on the same samples to obtain a correlation between the redox state and the fluorescence. It was found that illumination of PSII at temperatures between 85 and 260 K induced a fluorescence quenching state in two phases. At 85 K, where the fast phase was most prominent, only one electron-transfer pathway is active on the donor side of PSII. This pathway involves electron donation to the primary electron donor in PSII, P680, from cytochrome b559 and a redox-active chlorophyll molecule, ChlZ. Oxidized ChlZ was found to be a potent quencher of chlorophyll fluorescence with 15% of oxidized ChlZ sufficient to quench 70% of the fluorescence intensity. This implies that neighboring PSII reaction centers are energetically connected, allowing oxidized ChlZ in a few centers to quench most of the fluorescence. The presence of a well-defined quencher in PSII may make it possible to study the connectivity between antenna systems in different sample preparations. The other redox-active components on the donor side of PSII studied were the O2-evolving complex, the redox-active tyrosines (YZ and YD), and cytochrome b559. No significant changes in fluorescence intensity could be attributed to changes in the redox state of these components. The fast phase of fluorescence quenching is attributed to the rapid photooxidation of ChlZ, and the slow phase is attributed to multiple turnovers providing for further oxidation of ChlZ and irreversible photoinhibition. Significant photoinhibition only occurred at Chl concentrations below 0.7 mg/mL and above 150 K. The reversible oxidation of ChlZ in intact systems may function as a photoprotection mechanism under high-light conditions and account for a portion of the nonphotochemical fluorescence quenching.