Analyses of absorption and fluorescence spectra of water-soluble chlorophyll proteins, pigment system II particles and chlorophyll a in diethylether solution by the curve-fitting method.

Absorption and fluorescence spectra in the red region of water-soluble chlorophyll proteins, Lepidium CP661, CP663 and Brassica CP673, pigment System II particles of spinach chloroplasts and chlorophyll a in diethylether solution at 25 degrees C were analyzed by the curve-fitting method (French, C.S., Brown, J.S. and Lawrence, M.C. (1972) Plant Physiol 49, 421--429). It was found that each of the chlorophyll forms of the chlorophyll proteins and the pigment System II particles had a corresponding fluorescence band with the Stokes shift ranging from 0.6 to 4.0 nm. The absorption spectrum of chlorophyll a in diethylether solution was analyzed to one major band with a peak at 660.5 nm and some minor bands, while the fluorescence spectrum was analyzed to one major band with a peak at 664.9 nm and some minor bands. A mirror image was clearly demonstrated between the resolved spectra of absorption and fluorescence. The absorption spectrum of Lepidium CP661 was composed of a chlorophyll b form with a peak at 652.8 nm and two chlorophyll a forms with peaks at 662.6 and 671.9 nm. The fluorescence spectrum was analyzed to five component bands. Three of them with peaks at 654.8, 664.6 and 674.6 nm were attributed to emissions of the three chlorophyll forms with the Stokes shift of 2.0--2.7 nm. The absorption spectrum of Brassica CP673 had a chlorophyll b form with a peak at 653.7 nm and four chlorophyll a forms with peaks at 662.7, 671.3, 676.9 and 684.2 nm. The fluorescence spectrum was resolved into seven component bands. Four of them with peaks at 666.7, 673.1, 677.5 and 686.2 nm corresponded to the four chlorophyll a forms with the Stokes shift of 0.6--4.0 nm. The absorption spectrum of the pigment System II particles had a chlorophyll b form with a peak at 652.4 nm and three chlorophyll a forms with peaks at 662.9, 672.1 and 681.6 nm. The fluorescence spectrum was analyzed to four major component bands with peaks at 674.1, 682.8, 692.0 and 706.7 nm and some minor bands. The former two bands corresponded to the chlorophyll a forms with peaks at 672.1 and 681.6 nm with the Stokes shift of 2.0 and 1.2 nm, respectively. Absorption spectra at 25 degrees C and at --196 degrees C of the water-soluble chlorophyll proteins were compared by the curve-fitting methods. The component bands at --196 degrees C were blue-shifted by 0.8--4.1 nm and narrower in half widths as compared to those at 25 degrees C.     

Properties of oxygen-evolving photosystem-II particles from Phormidium laminosum, a thermophilic blue--green alga.

1. O2-evolving Photosystem-II particles from the thermophilic blue--green alga Phormidium laminosum contained 1 mol of Mn/13--17 mol of chlorophyll a compared with 1 mol of Mn/65--75 mol of chlorophyll a in unfractionated membranes. 2. At least two-thirds of the Mn in the Photosystem-II particles was removed by mild heating and by treatment with Tris or EDTA, with concomitant loss of O2 evolution. However, irreversible inactivation was also caused by washing in buffers without MgCl2, and this inactivation was not accompanied by a corresponding loss of Mn. 3. Bivalent cations (Mg2+ or Ca2+), Cl- or Br- ions and at least 20% (v/v) glycerol were required for maximum stability of O2 evolution. 4. The Photosystem-II particles were enriched in high-potential cytochrome b-559 (1 mol of cytochrome/50--60 mol of chlorophyll a) and in component C-550, and had a photosynthetic-unit size of 40--70 molecules of chlorophyll a. 5. The absorption spectrum at 77 K showed a preponderance of shorter-wavelength forms of chlorophyll a in the Photosystem-II particles, and in the fluorescence emission spectrum at 77 K there were major chlorophyll fluorescence bands at 684 nm and 695 nm, with almost no fluorescence in the far-red region. 6. Analysis of the lipid and protein contents showed that the Photosystem-II particles were not chemically pure (for example, all of the membrane-bound cytochromes and cytochrome c-549 were present), but their high O2-evolution activity and good optical properties make them useful for functional studies on Photosystem-II and O2 evolution.     

Determination of intracellular pH of BALB/c-3T3 cells using the fluorescence of pyranine

In terms of accuracy and sensitivity, intracellularly trapped, pH-dependent fluorescent probes are appropriate to accurately measure intracellular pH. These probes are commonly introduced into living cells in esterified form, wherein the free acid is produced through enzymatic hydrolysis. The fluorescence characteristics of the ester and the free acid can differ markedly and spectral uncertainty can occur. We describe here the measurement of intracellular pH using 8-hydroxypyrene-1,3,6-trisulfonic acid (pyranine) that has been scrape-loaded into BALB/c-3T3 mouse cells. The excitation spectrum of pyranine is pH sensitive, with an isosbestic point at 415 nm and peaks at 405 and 465 nm which decrease and increase with pH, respectively. The 465/405 ratio can be used to monitor the pH, while the fluorescence at 415 nm indicates the total dye-dependent signal remaining. The scrape-loaded dye persists in cells for periods up to 6 h. We have calibrated this dye in situ using nigericin/high K+, and have found that the pKa of the dye in situ is 7.82, as compared to 7.68 in vitro. We have observed that the cells can slowly equilibrate their intracellular pH to near control levels when presented with either an acute alkaline or acid load.     

Utraviolet adsorption and fluorescence of human thyroalbumin]

Some spectral properties of human thyroalbumin have been studied. Ultra-violet absorption of the aqueous solution of this protein has two maxima: at the wavelengths of 276 and 296--298 nm. Under the excitation by a monochromatic light with the wavelength of 280 nm the thyroalbumin has the fluorescence spectrum with the maximum at 430 nm and the quantum yeild of fluorescence about 5,4%. It has been established that thyroalbumin fluorescence consists of two components with the maxima at 385 and 450 nm. Moreover the "sortwave" component is principally attributed for by the presence do iodoamino acids.     

Comparison of helium-neon and dye lasers for the excitation of allophycocyanin

Allophycocyanin (APC) has a broad absorption spectrum permitting several different lasers to be used to excite this dye in a flow cytometer. A comparison was made between a dye laser and a helium-neon (HeNe) laser for the excitation of APC as an immunofluorescent chromophore. The ratio of fluorescence of stained to unstained lymphocytes (signal to background) was used to assess differences in sensitivity. In determining the best wavelength for operating the dye laser, it was found that there was little difference in the ability to separate the positive-labelled cells from the unstained cells using 600 nm or 633 nm light for excitation of APC. A study of the effect of laser power on the signal to background identified a nonlinear relationship. It was found that the sensitivity obtained with 47 mW of 633 nm light from a HeNe laser was near the maximum attainable. This sensitivity was comparable to that obtained using phycoerythrin as an immunofluorescence chromophore. APC had the added advantage of being applicable to the study of highly autofluorescent cells. Exciting this chromophore using red light dramatically decreased the autofluorescence observed even on alveolar macrophages.     

Photosensitivity spectrum of crayfish rhodopsin measured using fluorescence of metarhodopsin

Discrepancies exist among spectral measurements of sensitivity of crayfish photoreceptors, their absorption in situ, and the number and absorption spectra of crayfish photopigments that are extracted by digitonin solutions. We have determined the photosensitivity spectrum of crayfish rhodopsin in isolated rhabdoms using long wavelength fluorescence emission from crayfish metarhodopsin as an intrinsic probe. There is no measurable metarhodopsin in the dark-adapted receptor, so changes in the emission level are directly proportional to metarhodopsin concentration. We therefore used changes in metarhodopsin fluorescence to construct relaxation and saturation ("photoequilibrium") spectra, from which the photosensitivity spectrum of crayfish rhodopsin was calculated. This spectrum peaks at or approximately 530 nm and closely resembles the previously measured difference spectrum for total bleaches of dark-adapted rhabdoms. Measurements of the kinetics of changes in rhabdom fluorescence and in transmittance at 580 nm were compared with predictions derived from several model systems containing one or two photopigments. The comparison shows that only a single rhodopsin and its metarhodopsin are present in the main rhabdom of crayfish, and that other explanations must be sought for the multiple pigments seen in digitonin solution. The same analysis shows that there is no detectable formation of isorhodopsin in the rhabdom.     

The influence of pH on the absorption spectrum of arsenazo III.

The absorption spectrum of arsenazo III in media containing K+, Mg2+ and Ca2+ is sharply influenced by pH in the range of 7.5--5.0. The effect of pH is particularly pronounced in the wavelength range 532--602 nm due to the large pH dependence of the dissociation constant of Mg-arsenazo III complex. Therefore absorption changes at these wavelengths during muscle contraction cannot be used as reliable indicators of free ionized Ca2+ concentration in the cell. The effect of pH is less pronounced, but still noticeable at the wavelength pairs 575--650 or 660--685 nm. Multiple layers of muscle cells grown on polystyrene coils permit measurement of absorption changes of arsenazo III, introduced into the cells, by equilibration with 0.5 mM arsenazo III under routine culture conditions. The absorbance changes recorded at 660--685 nm are probably related to changes in intracellular free Ca2+ concentration.     

Antenna organization and evidence for the function of a new antenna pigment species in the green photosynthetic bacterium Chloroflexus aurantiacus

Whole cells and isolated chlorosomes (antenna complex) of the green photosynthetic bacterium Chloroflexus aurantiacus have been studied by absorption spectroscopy (77 K and room temperature), fluorescence spectroscopy, circular dichroism, linear dichroism and electron spin resonance spectroscopy. The chlorosome absorption spectrum has maxima at 450 (contributed by carotenoids and bacteriochlorophyll (BChl) a Soret), 742 (BChl c) and 792 nm (BChl a) with intensity ratios of 20:25. The fluorescence emission spectrum has peaks at 748 and 802 nm when excitation is into either the 742 or 450 nm absorption bands, respectively. Whole cells have fluorescence peaks identical to those in chlorosomes with the addition of a major peak observed at 867 nm. The CD spectrum of isolated chlorosomes has an asymmetric-derivative-shaped CD centered at 739 nm suggestive of exciton interaction at least on the level of dimers. Linear dichroism of oriented chlorosomes shows preferential absorption at 742 nm of light polarized parallel to the long axis of the chlorosome. This implies that the transition dipoles are also oriented more or less parallel to the long axis of the chlorosome. Treatment with ferricyanide results in the appearance of a 2.3 G wide ESR spectrum at g 2.002. Whole cells grown under different light conditions exhibit different fluorescence behavior when absorption is normalized at 742 nm. Cells grown under low light conditions have higher fluorescence intensity at 748 nm and lower intensity at 802 nm than cells grown under high light conditions. These results indicate that the BChl c in chlorosomes is highly organized, and transfers energy from BChl c (742 nm) to a connector of baseplate BChl B792 (BChl a) presumably located in the chlorosome baseplate adjacent to the cytoplasmic membrane.     

Spectrophotometry of individual Chlorella cells]

A research of optical properties of individual microalgae Chlorella vulgaris cells was performed under various conditions of cultivation. On the basis of cell absorption spectra measurements in the visible spectrum region chlorophyll "a" absorption maxima are estimated to fall within the intervals of 669-675 nm for the red region of the spectrum and 429--436 nm for the blue one. Concentration of chlorophylls in the cells of the diameter from 2,8 up to 3,3 micrometers was found to increase considerably for algae grown both in continuous denisty static and periodical regimes. Integral optical density of individual Chlorella cells in the range of 400-750 nm grows with cell diameter increase. This increase appears to be most intensive in the cells grown in density static regime. A correlation was also established between algae cell dimensions and the general maxima position (correlation coefficient has a positive sign and absolute value near unit). With cell diameter growth the absorption maxima shift to the region of long waves.     

Protochlorophyll forms with different molecular arrangements

Spectral properties of protochlorophyll (PChl) forms were investigated in solid-film model systems by absorption. fluorescence and circular dichroism (CD) spectroscopy. The solid films were prepared from diethyl ether solution of PChl on a cover glass surface by evaporation of the solvent. After preparation the films usually showed an absorption maximum at 635 nm or in some cases at 640 nm. The PChl form with 635 nm absorption maximum had no CD signal, whilst the films with absorption maximum at 640 nm gave an intense negative CD band at about 640 nm and a positive one at 668 nm. The treatment of the films with ammonia or acetone vapour resulted in a red shift of the absorption maximum from 635 nm or 640 nm to 650 nm. The study of the CD spectra of the films with different PChl forms showed that, depending on the treatment, forms of PChl with similar absorption and fluorescence spectra, but with opposite CD signals, can exist. It is suggested that the differences of the CD spectra are mainly due to different arrangements of the aggregates.     

Metallocytochromes c: characterization of electronic absorption and emission spectra of Sn4+ and Zn2+ cytochromes c.

Tin (Sn4+) and zinc (Zn2+) derivatives of horse heart cytochrome c have been prepared and their optical spectra have been characterized. Zinc cytochrome c has visible absorption maxima at 549 and 585 nm and Soret absorption at 423 nm. Tin cytochrome c shows visible absorption maxima at 536 and 574 nm and Soret absorption at 410 nm. Unlike iron cytochrome c in which the emission spectrum of the porphyrin is almost completely quenched by the central metal, the zinc and tin derivatives of cytochrome c are both fluorescent and phosphorescent. The fluorescence maxima of zinc cytochrome c are at 590 and 640 nm and the fluorescence lifetime is 3.2 ns. The fluorescence maxima of Sn cytochrome are at 580 and 636 nm and the fluorescence lifetime is under 1 ns. The quantum yield of fluorescence is Zn greater than Sn while the quantum yield of phosphorescence is Sn greater than Zn. at 77 K the fluorescence and phosphorescence emission spectra of Sn and Zn cytochrome c show evidence of resolution into vibrational bands. The best resolved bands occur at frequency differences 750 cm-1 and 1540--1550 cm-1 from the O-O transition. These frequencies correspond with those obtained by resonance Raman spectroscopy for in-plane deformations of the porphyrin macrocycle.     

Hemin (Fe(3+))-- and heme (Fe(2+))--smectite conjugates as a model of hemoprotein based on spectrophotometry

Hemin (Fe(3+)) was adsorbed onto synthetic smectite (clay mineral) in acetone to form a hemin-smectite conjugate. The hemin-smectite conjugate became soluble in water to form a transparent colloidal solution with a dark brown color. Its absorption spectrum in water showed a sharp Soret band at 398 nm with the molar extinction coefficient as epsilon(398nm) = 11.6 x 10(4) M(-1) cm(-1), which is in good agreement with epsilon(398nm) = (12.2 +/- 3) x 10(4) M(-1) cm(-1) of monomeric hematin (1). Hemin (Fe(3+))-smectite conjugate had a peroxidase-like activity in the presence of hydrogen peroxide (a hydrogen acceptor) and guaiacol (a hydrogen donor) in aqueous solution and its activity was higher than that of hematin. Hemin (Fe(3+))-smectite conjugate in water was reduced by adding sodium dithionite to form a heme (Fe(2+))-smectite conjugate which is also a transparent colloidal solution in water. Its absorption spectrum in aqueous solution was surprisingly in close agreement with that of oxyhemoglobin. Its peak positions of alpha, beta, and Soret bands were located in only a 9--3 nm shift to shorter wavelengths in comparison with those of oxyhemoglobin. Therefore, heme (Fe(2+))-smectite conjugate was bound to O(2) to form O(2)-heme (Fe(2+))-smectite conjugate. The addition of carbon monoxide, CO, to O(2)-heme (Fe(2+))-smectite conjugate caused the formation of CO-heme (Fe(2+))-smectite conjugate with a similar absorption spectrum of carboxyhemoglobin (HbCO) accompanied by shifting 8--10 nm to shorter wavelength. Therefore, the transformation of O(2)-heme (Fe(2+))-smectite conjugate to CO-heme (Fe(2+))-smectite conjugate was accompanied by shifting of 7, 4, and 3 nm to shorter wavelengths in the alpha, beta, and Soret bands respectively, which are similar to the spectral change from oxyhemoglobin to carboxyhemoglobin. Also the ratio (1:1.6) of the molar extinction coefficient of Soret band of O(2)-heme (Fe(2+))-smectite conjugate and CO-heme (Fe(2+))-smectite conjugate was surprisingly agreement with ratio (1:1.5) of oxyhemoglobin and carboxyhemoglobin. The phenomenon shown above was unexpectedly found during the course of study of bioconjugate of a bioactive substance, hemin (Fe(3+)) or heme (Fe(2+)), and a clay mineral, smectite, in place of the protein of globin in hemoglobin.     

Hematoporphyrin/DAPI staining: simplified simultaneous one-step staining of DNA and cell protein and trial application in automated cytological screening by flow cytometry

We describe a procedure for simplified, simultaneous one-step staining in 10 min for DNA and cell and tissue proteins using a newly developed staining solution containing 0.03% hematoporphyrin (HP) with 0.001% DAPI [or with Hoeschst 33342 (HO)]. These HP/DAPI or HP/HO solutions were especially developed to facilitate a trial of automated cancer cell screening on sputum samples using flow cytometry. Under UV light (365 nm) with fluorescence microscopy, HP/DAPI-stained cells showed red fluorescence (max. 670 nm) of cytoplasm and simultaneous blue fluorescence (max. 470 nm) of nuclei. The distance between the maximum peak of fluorescence spectra of DNA and that of protein was as large as 200 nm, and there was no detectable overlapping of each spectrum at the photometric filter range, which provided accurate measurement of DNA and protein. On flow cytometry, a single UV beam (370 nm) from the argon laser was used for excitation of both dyes. Measurement of DNA was done using a 470-nm bandpass filter and of protein using a 640-nm longpass (or 670-nm bandpass) filter. Reflecting the undetectable overlapping of the fluorescence spectra of protein and DNA, normal diploid cells in sputum revealed horizontal distributions along the 2C level on the dot-plot display of flow cytometry, which made sorting of abnormal hyperdiploid cells and cancer cells easier.     

Ratiometric fluorescence imaging of nuclear pH in living cells using Hoechst-tagged fluorescein

Small-molecule fluorescent sensors that allow specific measurement of nuclear pH in living cells will be valuable for biological research. Here we report that Hoechst-tagged fluorescein (hoeFL), which we previously developed as a green fluorescent DNA-staining probe, can be used for this purpose. Upon excitation at 405 nm, the hoeFL–DNA complex displayed two fluorescence bands around 460 nm and 520 nm corresponding to the Hoechst and fluorescein fluorescence, respectively. When pH was changed from 8.3 to 5.5, the fluorescence intensity ratio (F₅₂₀/F₄₆₀) significantly decreased, which allowed reliable pH measurement. Moreover, because hoeFL binds specifically to the genomic DNA in cells, it was applicable to visualize the intranuclear pH of nigericin-treated and intact living human cells by ratiometric fluorescence imaging.     

Analyses of absorption and fluorescence spectra of water-soluble chlorophyll proteins,pigment System II particles and chlorophyll a in diethylether solution by the curve-fitting method

Absorption and fluorescence spectra in the red region of water-soluble chlorophyll proteins, Lepidium CP661, CP663 and Brassica CP673, pigment System II particles of spinach chloroplasts and chlorophyll a in diethylether solution at 25°C were analyzed by the curve-fitting method (French, C.S., Brown, J.S. and Lawrence, M.C. (1972) Plant Physiol. 49, 421–429). It was found that each of the chlorophyll forms of the chlorophyll proteins and the pigment System II particles had a corresponding fluorescence band with the Stokes shift ranging from 0.6 to 4.0 nm.The absorption spectrum of chlorophyll a in diethylether solution was analyzed to one major band with a peak at 660.5 nm and some minor bands, while the fluorescence spectrum was analyzed to one major band with a peak at 664.9 nm and some minor bands. A mirror image was clearly demonstrated between the resolved spectra of absorption and fluorescence. The absorption spectrum of Lepidium CP661 was composed of a chlorophyll b form with a peak at 652.8 nm and two chlorophyll a forms with peaks at 662.6 and 671.9 nm. The fluorescence spectrum was analyzed to five component bands. Three of them with peaks at 654.8, 664.6 and 674.6 nm were attributed to emissions of the three chlorophyll forms with the Stokes shift of 2.0–2.7 nm. The absorption spectrum of Brassica CP673 had a chlorophyll b form with a peak at 653.7 nm and four chlorophyll a forms with peaks at 662.7, 671.3, 676.9 and 684.2 nm. The fluorescence spectrum was resolved into seven component bands. Four of them with peaks at 666.7, 673.1, 677.5 and 686.2 nm corresponded to the four chlorophyll a forms with the Stokes shift of 0.6–4.0 nm. The absorption spectrum of the pigment System II particles had a chlorophyll b form with a peak at 652.4 nm and three chlorophyll a forms with peaks at 662.9, 672.1 and 681.6 nm. The fluorescence spectrum was analyzed to four major component bands with peaks at 674.1, 682.8, 692.0 and 706.7 nm and some minor bands. The former two bands corresponded to the chlorophyll a forms with peaks at 672.1 and 681.6 nm with the Stokes shift of 2.0 and 1.2 nm, respectively.Absorption spectra at 25°C and at ?196°C of the water-soluble chlorophyll proteins were compared by the curve-fitting method. The component bands at ?196°C were blue-shifted by 0.8–4.1 nm and narrower in half widths as compared to those at 25°C.     

解离增强镧系元素荧光免疫分析灵敏度的改进

为提高解离增强镧系荧光免疫分析(DELFIA)的灵敏度或信／噪比,进行了一些重要的方法学研究．观察到了对于不同的铕量,荧光响应和信／噪比都随着增强液体积而明显地变化．对于确定的铕量,存在一个最佳体积,且铕量越小,其最佳体积也越小．实验中选择最佳体积是重要的．研究了增强液制备技术,发展了微滴定板条有效的清洗和干燥方法,使本底荧光明显降低．     

Elemental analysis using differential absorption techniques

X-ray differential absorption microanalysis is presented as a technique for trace element analysis of hydrated biological specimens of about 0.1–5 μm thickness. For the study of the light elements (Z?20), the absorption technique minimizes the radiation dose and, thus, damage to such specimens when compared with X-ray fluorescence. A Scanning Transmission X-ray Microscope (SXTM) is described, which has been used to map the concentration of calcium in bone with better than 300 nm spatial resolution and a sensitivity to 5% calcium by weight. Future plans are briefly discussed that offer the hope of achieving 0.1% trace element sensitivity and 75 nm spatial resolution.     

Purification and properties of phosphoglycerate kinase from Thermus thermophilus strain HB8.

(1) A glycolytic enzyme, phosphoglycerate kinase [EC 2.7.2.3], was purified from cells of an extreme thermophile, Thermus thermophilus strain HB8. The enzyme was resistant to heat, and no loss of activity was observed after incubation for 10--20 min at 79 degrees C. (2) Catalytic properties such as pH optimum (pH 6--8.5), kinetic parameters (Km=0.28 mM for ATP, 1.79 mM for glycerate 3-phosphate), substrate specificity and inhibitors of the enzyme were investigated and compared with those of phosphoglycerate kinase from other sources. (3) The enzyme protein consists of a single polypeptide chain of molecular weight 44,600. The isoelectric point is 5.0 The amino acid composition of the enzyme was studied. The contents of ordered secondary structures were estimated to be 29% alpha-helix and 11% pleated sheet from the circular dichroic spectrum of the enzyme protein. (4) The fluorescence spectrum of the enzyme protein showed an emission maximum at 320 nm when excited at 280 nm. The quantum yield was 0.19. Tryptophyl fluorescence was not quenched, in contrast to the fluorescence reported for yeast phosphoglycerate kinase.     

Measurement of transmembrane potentials in Rhodospirillum rubrum chromatophores with an oxacarbocyanine dye

The fluorescent dye 3,3-dipentyloxacarbocyanine (OCC) can be used as a fluorescence probe to measure transmembrane potentials across Rhodospirillum ruburm chromatophore membranes. A reversible fluorescence increase is observed in the light which is sensitive to inhibitors, permeable ions and uncouplers.Partial interchangeability between the electrical potential and the proton concentration gradient has been demonstrated by measurement of the fluorescence increase with OCC and the fluorescence quenching with 9-aminoacridine.OCC fluorescence changes can be induced also in the dark by injection of permeable salts and by rapid pH changes presumably indicating diffusion potentials. Using salt-induced diffusion potentials for calibrating the light signals and with several assumptions, the light-induced potentials were estimated as 170 mV for the maximal signal and 90–110 mV at the steady state.OCC has been shown to apparently increase the electrical conductivity of the chromatophore membrane, a fact which may be relevant to the mechanism of action of this probe.A red shift in the OCC absorption spectrum occurs when mixed with chromatophores, with a difference spectrum maximum at 495 nm. The absorption changes at 495 nm taking place in the light are similar in kinetics to the fluorescence changes. The absorbance spectrum of OCC in organic solvents is red shifted and the extent of the shift depends on the hydrophobicity of the medium. The difference spectrum compared to water in sec-butyl $\text{acetate}\text{n-}\text{hexane}$ (3 : 1, v/v) with a dipole moment of 5 was nearly identical to that of chromatophore-associated dye.The uncoupling properties of OCC at high concentrations and some difficulties in calibration limit the usefulness of this probe for quantitative measurements of transmembrane potentials.     

A comparison of the absorption changes near 325 nm and chlorophyll a fluorescence characteristics of the Photosystem II acceptors Qa and Q400

The stoichiometry of chlorophyll/Photosystem II was determined in pea thylakoids. The concentration of Photosystem II was determined by the absorption change at 325 nm. When the 325 nm measurement was made on the first flash in the presence of ferricyanide, the Photosystem II absorption change was found to increase by up to 100% of the same measurement made in the absence of ferricyanide. The increase in absorption change in the presence of various amounts of ferricyanide was found to correlate well with the increase in area above the Chl a fluorescence induction curve. Also, the dark recovery of both the 325 nm absorption change and the area above the Chl a fluorescence curve are similar and in the order of several minutes. Absorption changes made under repetitive flash excitation showed no increase in signal with the addition of ferricyanide. We conclude that there are two acceptors, Q_a and Q₄₀₀, for each active oxygen-evolving complex and only Q_a is involved in active electron transport to Photosystem I.