Counter-current distribution of sonicated inside-out thylakoid vesicles

Summary Inside-out thylakoid vesicles were isolated from spinach chloroplasts, and fragmented by sonication. Different fragments were separated by counter-current distribution and analyzed for chlorophyll and P700. The inside-out vesicles had a chlorophyll a/b ratio of 2.2–2.4 (original chloroplasts 2.8–3.0). After further fragmentation of the inside-out vesicles by sonication and separation by countercurrent distribution three populations of vesicles were obtained having chlorophyll a/b ratios of 1.7, 1.9 and 2.5 respectively. The P-700 was depleted in fractions with lower chlorophyll a/b ratio and was nearly absent in the fraction having a chlorophyll a/b ratio of 1.7 (chlorophyll/P700 > 4500 mol/mol). That PSII membrane vesicles, with such a low chlorophyll a/b ratio and lacking PSI, can be prepared by a non-detergent method provides strong support for the notion that PSI and PSII are segregated along the thylakoid membrane.A plot of P700 per chlorophyll against chlorophyll b/(a+b) fits a straight line connecting the pure PSI membrane (chlorophyll a/b = 6; P700/chlorophyll = 5.6 mmol/mol) with the pure PSII membrane (chlorophyll a/b = 1.7; P700 = 0). These two membranes can be considered as separate phases of a two-dimensional phase system. Models for the thylakoid membrane are discussed.Abbreviations PSI Photosystem I - PSII Photosystem II - PEG Polyethylene Glycol - P700 Reaction Center of PSI     

Fractionation of the thylakoid membranes from tobacco. A tentative isolation of 'end membrane' and purified 'stroma lamellae' membranes

Thylakoids isolated from tobacco were fragmented by sonication and the vesicles so obtained were separated by partitioning in aqueous polymer two-phase systems. By this procedure, grana vesicles were separated from stroma exposed membrane vesicles. The latter vesicles could be further fractionated by countercurrent distribution, with dextran-polyethylene glycol phase systems, and divided into two main populations, tentatively named 'stroma lamellae' and 'end membrane'. Both these vesicle preparations have high chlorophyll a/b ratio, high photosystem (PS) I and low PS II content, suggesting their origin from stroma exposed regions of the thylakoid. The two vesicle populations have been compared with respect to biochemical composition and photosynthetic activity. The 'end membrane' has a higher chlorophyll a/b ratio (5.7 vs. 4.7), higher P700 content (4.7 vs. 3.3 mmol/mol of chlorophyll). The 'end membrane' has the lowest PS II content, the ratio PS I/PS II being more than 10, as shown by EPR measurements. The PS II in both fractions is of the beta-type. The decay of fluorescence is different for the two populations, the 'stroma lamellae' showing a very slow decay even in the presence of K3Fe(CN)6 as an acceptor. The two vesicle populations have very different surface properties: the end membranes prefer the upper phase much more than the stroma lamellae, a fact which was utilized for their separation. Arguments are presented which support the suggestion that the two vesicle populations originate from the grana end membranes and the stroma lamellae, respectively.     

Fragmentation and separation analysis of the photosynthetic membrane from spinach

Membrane vesicles, originating from grana, grana core (appressed grana regions), grana margins and stroma lamellae/end membranes, were analysed by counter current distribution (CCD) using aqueous dextran-polyethylene glycol two-phase systems. Each vesicle population gave rise to distinct peaks in the CCD diagram representing different vesicle subpopulations. The grana vesicles and grana core vesicles each separated into 3 different subpopulations having different chlorophyll a/b ratios and PSI/PSII ratios. Two of the grana core subpopulations had a chlorophyll a/b ratio of 2.0 and PSI/PSII ratio of 0.10 and are among the most PSII enriched thylakoid vesicle preparation obtained so far by a non detergent method. The margin vesicles separated into 3 different populations, with about the same chlorophyll a/b ratios, but different fluorescence emission spectra. The stroma lamellae/end membrane vesicles separated into 4 subpopulations. Plastoglobules, connected to membrane vesicles, were highly enriched in 2 of these subpopulations and it is proposed that these 2 subpopulations originate from stroma lamellae while the 2 others originate from end membranes. Fragmentation and separation analysis shows that the margins of grana constitute a distinct domain of the thylakoid and also allows the estimation of the chlorophyll antenna sizes of PSI and PSII in different thylakoid domains.     

Countercurrent-distribution studies on histones

1. The possibilities of fractionating histones and histone fractions by means of countercurrent distribution between two phases formed by water and butan-2-ol, in the presence of various concentrations of trichloroacetic acid, have been examined. 2. Although the principal histone fractions differ considerably in their partition ratios, a satisfactory resolution of the principal histone fractions from the whole histone has not been achieved. 3. The histone fractions obtained by other methods can be resolved with suitable concentrations of trichloroacetic acid. Besides the main peak several subsidiary peaks are obtained in most cases, the composition of which corresponds with others of the main fractions. 4. The method is therefore capable of removing from the principal fractions as previously prepared contamination by other fractions. 5. Except in one case, no fraction with composition unlike other fractions has been obtained. In several cases the material isolated from the principal peak behaves as a single component on running again. In two cases fractions with similar compositions were distinguished by countercurrent distribution.     

Composition of photosynthetic pigments in thylakoid membrane vesicles from spinach

Thylakoid membranes from spinach were fragmented mechanically and separated into vesicles originating from grana and stroma-exposed lamellae (Andreasson et al. (1988) Biochim Biophys Acta 936: 339–350). The grana vesicles were further fragmented and separated into smaller vesicles originating from different parts of the grana (Svensson and Albertsson (1989) Photosynth Res 20: 249–259). All vesicles so obtained were analyzed with respect to chlorophyll and carotenoid composition by reverse phase HPLC. For all fractions the following relations (mole/mole) were found: 1 carotenoid per 4 chlorophyll (a+b), 2 lutein per 5 chlorophyll b and 5 violaxanthin per 100 chlorophyll (a + b). The contents of lutein and neoxanthin were each linearly related to chlorophyll b and -carotene was linearly related to chlorophyll a.     

Plasma membrane vesicles of opposite sidedness from soybean hypocotyls by preparative free-flow electrophoresis

Absolute orientations (sidedness) of plasma membrane vesicles obtained in highly purified fractions by preparative free-flow electrophoresis and by aqueous two-phase partition were determined based on ATPase latency and morphological criteria. Free-flow electrophoresis yielded two plasma membrane fractions. One, the least electronegative and designated fraction `E,' was pure plasma membrane. The other, more electronegative and designated fraction `C,' was heavily contaminated by various other cellular membranes. Plasma membrane vesicles from both fraction C and fraction E partitioned into the upper phase with aqueous two-phase partitioning. Purified plasma membrane obtained from microsomes by two-phase partition (upper phase) when subjected to free-flow electrophoresis also yielded two fractions, one fraction co-migrated with fraction C and another fraction co-migrated with fraction E. Both fractions exhibited an ATPase activity sensitive to vanadate and insensitive to nitrate and azide. ATPase activity was used as a structure-linked latency marker for the inner membrane surface. Concanavalin A binding (linked to peroxidase) was used as an imposed electron microscope marker for the outer membrane surface. Fraction E vesicles showed low ATPase latency (two-fold or less) and weak reactivity with concanavalin A peroxidase. In contrast, fraction C vesicles were characterized by much greater latencies upon detergent treatment (sevenfold) and a strong reaction with concanavalin A peroxidase. Two-phase partition as the initial procedure for plasma membrane isolation, yielded mixtures of vesicles of both inside out and right-side out orientation. Free-flow electrophoresis resolved the plasma membrane isolates into vesicles from fraction C which were right-side out (cytoplasmic side in), and vesicles from fraction E which were wrong-side out (cytoplasmic side out). Therefore, the two methods used in series, provided highly purified membrane preparations of apparently homogenous vesicles of opposite known absolute orientations.     

Alterations in membrane surface properties during cell differentiation as measured by partition in aqueous two-polymer phase systems: Rat intestinal epithelial cells

Membrane surface properties of rat intestinal epithelial cells (crypt base to villus tips) were studied by cell partition in a two-polymer aqueous phase system. A higher partition generally reflects higher cell surface charge (or charge-associated properties) which is not necessarily the same as the charge determined by cell electrophoresis since the latter reflects only the charge at the plane of shear while the former gauges it deeper into the membrane [10]. Cells were prepared by the method of Weiser [22] which sequentially yields cell fractions from villus tips to crypt base. The isolated cells were subjected to countercurrent distribution in a dextran-polyethylene glycol aqueous two-phase system. Countercurrent distribution on the first fractions obtained by Weiser's method have a peak to the left and a smaller peak to the right indicating a surface membrane heterogeneity of upper villus cells; last fractions have a peak only to the right. When all fractions are pooled before countercurrent distribution two well-separated peaks are obtained with the right peak sometimes showing additional heterogeneities. Experiments combining isotope labeling of cells with countercurrent distribution lead us to conclude that the membrane charge (or charge-associated properties) of crypt base cells increases during differentiation and that the charge of the villus cells to which they give rise then diminishes during maturation. The charge of the bulk of the upper villus cells is the lowest of any in the intestinal cell population. The basis for the alteration in charge has not been established but the phenomenon of changing membrane surface charge (or charge-associated properties) as a function of cell differentiation, maturation and aging appears to be a general phenomenon having been found and traced in different cell populations [14, 16, 17, 28].     

Separation of presumptive plasma membranes from mitochondria by partition in an aqueous polymer two-phase system

Light-induced absorbance changes (LIAC), indicating the reversible reduction of a b-type cytochrome, and with a possible connection to blue light photomorphogenesis, have been found in a presumptive plasma membrane rich centrifuge fraction from LIAC could be due to plasma membrane vesicles turned inside out or to cytochromes localized in other organelles. Phase partition proved to be a rapid method (results technique membrane particles are separated according to differences in surface properties rather than size and density. LIAC could be separated into two fractions: one partitioning into the polyethylene glycol rich upper phase and another preferring the dextram rich lower phase. Mitochondria (cytochrome c oxidase) were recovered in the lower phase. A dual distribution of LIAC was found with all materials tested: corn coleoptiles, corn shoots, barley shoots and cauliflower inflorescences. About 80–90% of the cytochromes in the upper phase were related to LIAC, whereas only 10–15% of those in the lower phase were of this kind. The LIAC preferring the upper phase was probably bound to the plasma membrane, since plasma membrane vesicles are known to have a high partition in these phase systems. The lower phase LIAC could be due to plasma membrane vesicles turned inside out or to cytochromes localized in other organelles. Phase partition proved to be a rapid method (results within one hour after the initial pelleting) for purification of presumptive plasma membranes, yielding a preparation which contained five times less mitochondrial contamination than the preparation obtained with sucrose gradient centrifugation (the 33/45% w/w sucrose interface fraction).     

The uptake of Na-selenite in rat brain

Polyunsaturated fatty acids (PUFAs) occur in phospholipids of synapses of central nervous system (CNS). PUFAs may thus determine the fluidity of synaptosomal membranes and regulate neuronal transmission. It was therefore tempting to suggest an oxidative system in CNS protecting the membrane function, e.g., glutathione peroxidase (GSH-Px). In order to trace GSH-Px Wistar rats were loaded with 4800 kBq of⁷⁵Se sodium selenite. By means of gradient ultracentrifugation, particulate fractions of CNS were isolated and radioactivity as well as selenium dependent GSH-Px were estimated. The following data were obtained:

1. All fractions (myelin, synaptic vesicles, synaptosomes, mitochondria, and microsomes) contained⁷⁵Se.
2. After acetone precipitation of GSH-Px activity, fractionation on Sephadex G-150 revealed in all particulate fractions at least two peaks of radioactivity with GSH-Px activity.
3. The two GSH-Px peaks from the Sephadex filtration were freeze dried and applied on a hydrophobic T-gel column and eluted with decreasing molarity of ammonium sulfate from 1.5 to 0.05M. The first Sephadex peak with GSH-Px activity from myelin and the second peak with GSH-Px activity from synaptic vesicles could now be resolved into two different fractions of radioactivity on the T-gel. The remaining Sephadex G-150 peaks could only be resolved into one peak of radioactivity.
4. SDS-polyacrylamide gel electrophoresis of the T-gel peaks from all fractions showed a protein band with a mobility identical with that of human erythrocyte GSH-Px. The T-gel elution of myelin, synaptic vesicles and mitochondria gave rise to nearly pure CNS GSH-Px activity.

. The data presented support the idea that CNS fractions have membrane bound GSH-Px activity that may function as protecting enzymes towards oxidative stress in the brain.     

Studies on the heterogeneity of sarcoplasmic reticulum vesicles.

Isolated sarcoplasmic reticulum vesicles from rabbit white muscle were separated into a light (15--20% of total microsomes) and a heavy (80--85%) fraction by density gradient centifugation. The ultrastructure, chemical composition, enzymic activities and localization of membrane components in the vesicles of both fractions were investigated. From the following results it was concluded that both fractions are derived from the membranes of the sarcoplasmic reticulum system of the muscle: (i) The protein pattern of both fractions is essentially the same, except for different ratios of acidic, Ca2+-binding proteins. (ii) The 105000 dalton protein of the light fraction cross-reacts immunologically with the Ca2+-dependent ATPase of the heavy fraction. (iii) Ca2+-dependent ATPase, although of different specific activity, is found in both fractions. After rendering the vesicles leaky, specific activities in both fractions reach the same value. The light fraction was found to consist of "inside-out" vesicles by the following criteria: (i) No Ca2+ accumulation can be measured and the Ca2+-dependent ATPase activity is low and variable. (ii) The rate of trypsin digestion is lower and, compared to the heavy microsomes, a different ratio of degradation products is obtained. (iii) The sarcoplasmic reticulum membrane has a highly asymmetrical lipid distribution. This distribution of aminophospholipids is opposite to that in vesicles of heavy fraction. The light sarcoplasmic reticulum fraction has a higher phospholipid to protein ratio than the heavy one. This is consistent with the possibility that the two fractions derive from different parts of the sarcoplasmic reticulum system.     

Separation of rat leukocytes by countercurrent distribution in aqueous two-phase systems. I. Characterization of subpopulations of cells.

Cells from rat spleen, lymph nodes, and thoracic duct were separated by countercurrent distribution in aqueous two-polymer phase systems containing dextran and polyethylene glycol. Lymphoid cells from the different organs gave distinct, highly reproducible distribution patterns. The yield of separated cells and their viability compared well with other methods of physical separation. The majority of the leukocytes was separated from erythrocytes. Cells with surface immunoglobulin were recovered in one side of the distribution, while thymus-derived lymphocytes as determined by indirect immunofluorescence and histochemical staining were found in all fractions. However, cells responding to PHA and Con A were concentrated in a small area of the distribution, indicating a separation of subpopulations of thymus-derived lymphocytes.     

Fractionation of human neutrophils into subpopulations by countercurrent distribution: surface charge and functional heterogeneity.

Isolated blood neutrophils from normal healthy subjects were separated into fractions by sequential countercurrent distribution (CCD) in a charge-sensitive dextran/polyethylene glycol aqueous phase system. The neutrophils separated as a broad profile, and in a charged phase procedure the separation was based upon differences in cell surface electrokinetic properties, as confirmed by electrophoretic mobility measurements of fractions across the profile using analytical cytopherometry. The CCD cell fractions were generally pooled as three or four major subfractions for analysis of functional and metabolic differences. These included measurements of chemotaxis, phagocytosis, and respiratory burst. An inverse relationship was found between the electrophoretic mobility (EPM) of the subfraction pools and their functional competence, with the less electronegative cell fraction pools often as much as 2 to 3-fold more active than the more electronegative pools. This demonstration of electrokinetic and functional heterogeneity in 'resting' neutrophil subpopulations separated by CCD may reflect changes during their sojourn in the circulation that determine selective margination and recruitment of cells to inflammatory foci and sites of infection.     

On the presence of inside-out plasma membrane vesicles and vanadate-inhibited K+,Mg2+-ATPase in microsomal fractions from wheat and maize roots

We have estimated the amount of inside-out plasma membrane (PM) vesicles in microsomal fractions from wheat (Triticum aestivum L. cv. Drabant) and maize (Zea mays L.) roots; non-latent activities of the PM markers vanadate-inhibited K⁺, Mg²⁺-ATPase (ΔVO₄-ATPase) and glucan synthase II (GS II, EC 2.4.1.34) were used as markers for inside-out PM vesicles, latent activities as markers for right-side-out PM vesicles, and specific staining with silicotungstic acid (STA) as a general marker for the PM. Separation of presumptive inside-out PM vesicles from right-side-out ones was achieved by counter-current-distribution (CCD) in an aqueous polymer two-phase system. Most of the GS II activity was latent and was found in material partitioning into the upper phase; a distribution which correlated well with that of STA-stained vesicles. Thus, most of the PM vesicles had a right-side-out orientation. ΔVO₄-ATPase, on the other hand, had a dual distribution (particularly pronounced in wheat) and was recovered both in material partitioning into the lower phase and into the upper phase. This indicates that ΔVO₄-ATPase activity was present also in membranes other than the PM. Additional evidence for this interpretation came from sucrose gradient centrifugation of wheat root material. This produced two peaks of ΔVO₄-ATPase activity with the membranes partitioning into the lower phase, none of which coincided with the peak obtained with right-side-out PM vesicles. Taken together, these results indicate that only very few inside-out PM vesicles are present in the microsomal fraction, and that ΔVO₄-ATPase as a marker for the PM, in contrast to GS II, may give quite misleading results with some plant materials. This stresses the need to use well-defined preparations of scaled, inside-out PM vesicles in solute uptake studies. The distribution of Ca²⁺-inhibited ATPase, on the other hand, agreed well with those of GS II and STA-stained vesicles both after CCD and sucrose gradient centrifugation, which suggests that Ca²⁺ inhibition may be a more specific property of the PM H⁺-ATPase than vanadate inhibition.     

Reduction of 2,6-dichlorophenol-indophenol (Hill Reaction) by Chloroplasts with Different Chlorophyll a/b Ratios Under monochromatic Light

Chloroplasts with different chlorophyll a/b ratios were isolated from 7 to 8 days old wheat seedlings and the activities of reduction of 2,6-dichlorophenol-indophenol (DPIP) by these chloroplasts as function of the chlorophyll a/b ratios were studied under mono-chromatic light (650 m μ, 670 mμ, 680 mμ, 707 mμ). It was found that the DPIP reducing activities by these chloroplasts varied with their chlorophyll a/b ratios, and these variations are affected by the wavelengths of the illuminating light. Under 650 mμ, at the a/b ratios of 2.2 to 2.82, the activities of DPIP reduction in- creased with the a/b ratios, but decreased when the a/b ratios were higher than 2.82. Under 670 mμ, the DPIP reducing activities also varied with the a/b ratios of isolated chloroplasts. However, the variation was more gradual and steadier. Under 680 mμ, the DPIP reducing activities increased with the a/b ratios over 3.0, but decreased rather suddenly at a/b ratio of 3.30. Essentially the same relation held for 707 mμ, but the Hill reaction activities ceased to decline farther when a/b ratio rose to 3.40 at 707 mμ. When the results were analyzed in terms of the “relative activities” of the chloroplasts of the above mentioned wave lengths, it was found that the values of the "relative activity" (a/a+b) declined steadily from 1.47–1.29 at an a/b ratio range of 2.05–3.40, while the values of the "relative activity" (b/a+b)increased steadily from 3.10--4.40 at the same range of a/b ratios. But it is to be noted that, under 650 mμ, the (a/a+b) was 1.36 at the a/b ratio range of 2.63–2.82. Interesting enough, the DPIP reducing activities were the highest of all with these a/b ratios. Activities of DPIP reduction by isolated chloroplasts kept at 0 ℃, 20 ℃, 30 ℃, and 45 ℃ diminished with time when illuminated at all wavelengths. However, for those kept at 45 ℃ their activities were lost after 20 minutes, except those illuminated with the wave length of 680 mμ which still maintained 30 % of the initial activity. When kept at the above mentioned temperatures, the chlorophyll a/b ratios of all batches of chloroplasts declined steadily with time. The above results are interpreted as being indicative of the possibility that the pigment systems for the partial reaction (Hill reaction) of the over-all photosynthesis process consisted mainly of Chlb650 and Chla670. And the correlation of temperature and abolition of activity reduction of DPIP of chloroplasts varied under monochromatic light of different wave lengths.     

Subfractionation of rat liver microsomes by immunoprecipitation and immunoadsorption methods.

Rabbit antisera were prepared against cytochrome b5 and NADPH-cytochrome c reductase [EC 1.6.2.4] purified from rat liver microsomes, and utilized in examining the distribution of these and other membrane-bound enzymes among the vesicles of rat liver microsomal preparations by immunoprecipitation and immunoadsorption methods. Smooth microsomes with an average vesicular size of 200 nm (diameter) and sonicated smooth microsomes with an average diameter of 40-60 nm were used in subfractionation experiments. Immunoprecipitation of microsomal vesicles with anti-cytochrome b5 immunoglobulin failed to show any separation of the microsomes into fractions having different enzyme compositions. Cytochrome b5 was apparently distributed among all vesicles even when sonicated microsomes were used. When the antibody against NADPH-cytochrome c reductase was used, however, immunoadsorption of microsomes on Sepharose-bound antibody produced some separation of NADPH-cytochrome c reductase and cytochrome P-450 from NADH-cytochrome b5 reductase and cytochrome b5. The separation was more pronounced when sonicated microsomes were used. These results indicate microheterogeneity of the microsomal membrane, and suggest the clustering of NADPH-cytochrome c reductase and cytochrome P-450 molecules in the membrane.     

Separation of subchloroplast membrane particles by counter-current distribution

Counter-current distribution in an aqueous Dextran-polyethylene glycol two-phase system has been used to fractionate membrane fragments obtained by press treatment of Class II chloroplasts. By the counter-current distribution technique membrane particles are separated according to their surface properties such as charge and hydrophobicity.The fractions obtained were analysed with respect to photochemical activities, chlorophyll and P-700 contents. The Photosystem II enrichment after counter-current distribution was better than that obtained by differential centrifugation of the disrupted chloroplasts. However, the best separation of Photosystem I and II enriched particles could be achieved if differential centrifugation was combined with the counter-current distribution technique.Each centrifugal fraction could be further separated into Photosystems I and II enriched fractions since the Photosystem II particles preferred the dextran-rich bottom phase while the Photosystem I particles preferred the polyethylene glycol-rich top phase. By this procedure it was possible, without the use of detergents, to obtain vesicles which were more enriched in Photosystem II as compared to intact grana stacks.The partition behaviour of undisrupted Class II chloroplasts and the Photosystem I centrifugal fraction was the same. This similarity indicates that the membrane which is exposed to the surrounding polymers by the Class II chloroplasts is the Photosystem I rich membrane of the stroma lamellae.     

Fractionation of chromosomal deoxyribonucleoproteins by partition in two-phase aqueous polymer systems

Deoxyribonucleoprotein (DNP)¹ prepared by shearing chromatin of mouse cells may be fractionated in 2-phase aqueous Dextran-polyethyleneglycol mixtures. A partial separation of DNPs with different non-histone protein/DNA ratios may be obtained in a single-step partition. Separation of a spectrum of fractions of DNP has been obtained by countercurrent distribution using the same 2-phase polymer system. DNP fractions which bear nascent RNA (representing approximately $\text{1}\text{3}$ of the total DNA) may be separated from the major fraction of DNP; they are found in the same region of the distribution pattern as DNP fractions with the highest non-histone protein/DNA ratio.     

Characterization of a non-detergent PS II-cytochrome b/f preparation (BS)

A non-detergent photosystem II preparation, named BS, has been characterized by countercurrent distribution, light saturation curves, absorption spectra and fluorescence at room and at low temperature (–196°C). The BS fraction is prepared by a sonication-phase partitioning procedure (Svensson P and Albertsson P-Å, Photosynth Res 20: 249–259, 1989) which removes the stroma lamellae and the margins from the grana and leaves the appressed partition region intact in the form of vesicles. These are closed structures of inside-out conformation. They have a chlorophyll a/b ratio of 1.8–2.0, have a high oxygen evolving capacity (295 mol O₂ per mg chl h), are depleted in P700 and enriched in the cytochrome b/f complex. They have about 2 Photosystem II reaction centers per 1 cytochrome b/f complex.The plastoquinone pool available for PS II in the BS vesicles is 6–7 quinones per reaction center, about the same as for the whole thylakoid. It is concluded, therefore, that the plastoquinone of the stroma lamellae is not available to the PS II in the grana and that plastoquinone does not act as a long range electron transport shuttler between the grana and stroma lamellae.Compared with Photosystem II particles prepared by detergent (Triton X-100) treatment, the BS vesicles retain more cytochrome b/f complex and are more homogenous in their surface properties, as revealed by countercurrent distribution, and they have a more efficient energy transfer from the antenna pigments to the reaction center.Abbreviations DCMU 3-(3,4-dichlorophenyl)-1,1-dimethylurea - F_v variable fluorescence - LHC light-harvesting complex - PpBQ phenyl-p-benzoquinone - PQ plastoquinone pool - P700 reaction center of PS I - PS I, PS II Photosystem I, II - Q_A first bound plastoquinone accepter - RC reaction centre     

Separation of subchloroplast membrane particles by counter-current distribution.

Counter-current distribution in an aqueous Dextran-polyethylene glycol two-phase system has been used to fractionate membrane fragments obtained by press treatment of Class II chloroplasts. By the counter-current distribution technique membrane particles are separated according to their surface properties such as charge and hydrophobicity. The fractions obtained were analysed with respect to photochemical activities, chlorophyll and P-700 contents. The Photosystem II enrichment after counter-current distribution was better than that obtained by differential centrifugation of the disrupted chloroplasts. However, the best separation of Photosystem I and II enriched particles could be achieved if differential centrifugation was combined with the counter-current distribution technique. Each centrifugal fraction could be further separated into Photosystems I and II enriched fractions since the Photosystem II particles preferred the dextran-rich bottom phase while the Photosystem I particles preferred the polyethylene glycol-rich top phase. By this procedure it was possible, without the use of detergents, to obtain vesicles which were more enriched in Photosystem II as compared to intact grana stacks. The partition behaviour of undisrupted Class II chloroplasts and the Photosystem I centrifugal fraction was the same. This similarity indicated that the membrane which is exposed to the surrounding polymers by the Class II chloroplasts is the Photosystem I rich membrane of the stroma lamellae.     

Identification of Tetrahymena Ciliary Surface Proteins Labeled with Sulfosuccinimidyl 6-(Biotinamido) Hexanoate and Concanavalin A and Fractionated with Triton X-114

ABSTRACT. Tetrahymena thermophila cells were labeled with sulfosuccinimidyl 6-(biotinamido) hexanoate, a sensitive nonradioactive probe for cell surface proteins, and Western blots of axonemes and ciliary membrane vesicles were compared to cilia fractionated with Triton X-114 (TX-114) in order to study the orientation of ciliary membrane proteins. Greater than 40 ciliary surface polypeptides, from >350 kDa to <20 kDa, were resolved. The major surface 50–60 kDa proteins are hydrophobic and partition into the TX-114 detergent phase. Two high molecular weight proteins, one of which is biotinylated, comigrate with the heavy chains of ciliary dynein, sediment at 14S in a sucrose gradient, and partition into the TX-114 aqueous phase. Fractions containing these high molecular weight proteins as well as fractions enriched in 88-kDa and 66-kDa polypeptides contain Mg²⁺-ATPase activities. Detergent-solubilized tubulins partition into the TX-114 aqueous phase, are not biotinylated, and must not be exposed to the ciliary surface. The detergent-insoluble axoneme and membrane fraction contains a 36-kDa polypeptide and a portion of the 50-kDa polypeptides that otherwise partition into the detergent phase. These polypeptides could not be solubilized by ATP or by NaCl extraction and appear to be associated with pieces of ciliary membrane tightly linked to the axoneme. The ciliary membrane polypeptides were also tested for Concanavalin A binding and at least sixteen Con A-binding polypeptides were resolved. Of the major Con A-binding polypeptides, three are hydrophobic and partition into the TX-114 detergent phase, three partition into the TX-114 aqueous phase, and four partition exclusively in the detergent-insoluble fraction, which contains axonemes and detergent-resistant membrane vesicles.