High resolution analysis of the formation of cellulose synthesizing complexes inVaucheria hamata

Summary Ultrastructure and assembly of cellulose terminal synthesizing complexes (terminal complexes, TCs) in the algaVaucheria hamata (Waltz) were investigated by high resolution analytical techniques for freeze-fracture replication.Vaucheria TCs consist of many diagonal rows of subunits located on the inner leaflet of the plasma membrane. Each row contains about 10–18 subunits. The subunits themselves are rectangular, approx. 7×3.5 nm, and each has a single elliptical hole which may be the site of a single glucan chain polymerization. The subunits are connected with extremely small filaments (0.3–0.5 nm). Connections are more extensive in a direction parallel to the subunit rows and less extensive perpendicular to them. Nascent TC subunits are found to be packed within globules (15–20 nm in diameter) which are larger than typical intramembranous particles (IMPS are 10–11 nm in diameter) distributed in the plasma membrane. The subunits in the globule, which may be a zymogenic precursor of the TC, are generally exhibited in the form of doublets. Approximately 6 doublets are connected to a center core with small filaments. The globules are inserted into the plasma membrane together with IMPS by the fusion of cytoplasmic (Golgi derived) vesicles. Two or three globules attach to each other, unfold, and expand to form the first subunit rows of the TC on the inner leaflet of the plasma membrane. More globules attach to the structure and unfold until the nascent TC consists of a few rows of subunits. These rows are arranged almost parallel to each other. Two formation centers of subunits appear at both ends of an elongating TC. New subunits carried by the globules are added at each of these centers to create new rows until the elongating TC structure is completed. On the basis of this study, a model of TC assembly and early initiation of microfibril formation inVaucheria is proposed.Abbreviations IMPS intramembranous particles - MF microfibril - TC terminal complex     

The Lipid Phase of Thylakoid and Cytoplasmic Membranes from the Blue-Green Algae (Cyanobacteria), Anacystis nidulans and Anabaena variabilis

The lipid phases of the thylakoid and cytoplasmic membranesfrom the blue-green alga, Anacystis nidulans, were studied bya spin-probe method using 2-(14-carboxytetradecyl)-2-ethyl-4,4-dimethyl-3-oxazolidinyloxyl.The thylakoid and cytoplasmic membranes of this alga were bothin the liquid crystalline state at growth temperature, and inthe phase separation state at about 0?C. The thylakoid membranesentered the phase separation state at a temperature higher thanthe cytoplasmic membranes. The lipid phase of the thylakoidmembranes from Anabaena variabilis was studied in a similarway, and these membranes were found also to undergo the phasetransition. The temperature for the onset of the phase separationand the fluidity of the membrane lipids of both algae dependedon the growth temperature of the culture. (Received April 9, 1984; Accepted June 1, 1984)     

Mechanism and regulation of GLUT-4 vesicle fusion in muscle and fat cells

Twenty years ago it was shown that recruitment ofglucose transporters from an internal membrane compartment to theplasma membrane led to increased glucose uptake into fat and musclecells stimulated by insulin. The final step of this process is thefusion of glucose transporter 4 (GLUT-4)-containing vesicles with the plasma membrane. The identification of a neuronal solubleN-ethylmaleimide-sensitive factor attachment proteinreceptor (SNARE) complex as a requirement for synaptic vesicle-plasmamembrane fusion led to the search for homologous complexes outside thenervous system. Indeed, isoforms of the neuronal SNAREs were identifiedin muscle and fat cells and were shown to be required for GLUT-4incorporation into the cell membrane. In addition, proteins that bindto nonneuronal SNAREs were cloned and proposed to regulate vesiclefusion. We have summarized the molecular mechanisms leading to membranefusion in nonneuronal systems, focusing on the role of SNAREs andaccessory proteins (Munc18c, synip, Rab4, and VAP-33) in incorporationof GLUT-4 into the plasma membrane. Potential modes of regulation ofthis process are discussed, including SNARE phosphorylation andinteraction with the cytoskeleton.

     

Regulation of Photosystem Stoichiometry in the Photosynthetic System of the Cyanophyte Synechocystis PCC 6714 in Response to Light-Intensity

Light-induced changes in stoichiometry among three thylakoidcomponents, PS I, PS II and Cyt b₆-f complexes, were studiedwith the cyanophyte Synechocystis PCC 6714. Special attentionwas paid to two aspects of the stoichiometric change; first,a comparison of the patterns of regulation in response to differencesin light-intensity with those induced by differences in light-quality,and second, the relationship between regulation of the stoichiometryand the steady state of the electron transport system. Resultsfor the former indicated that (1) the abundance of PS I on aper cell basis was reduced under white light at the intensityas high as that for light-saturation of photosynthesis, butPS I per cell was increased under low light-intensity, (2) PSII and Cyt b₆-f complexes remained fairly constant, and (3)changes in the abundance of PS I depended strictly on proteinsynthesis. The pattern was identical with that of chromaticregulation. For the second problem, the redox steady-statesof Cyt f and P700 under white light of various intensities weredetermined by flash-spectroscopy. Results indicated that (1)Cyt f and P700 in cells grown under low light-intensity [highratio of PS I to PS II (PS I/PS II)] were markedly oxidizedwhen the cells were exposed to high light-intensity, while theyremained in the reduced state under low light-intensity. (2)After a decrease in the abundance of PS I, most of P700 remainedin the reduced state even under high light-intensity, whilethe level of reduced Cyt f remained low. (3) Both Cyt f andP700 in cells of low PS I/PS II were fully reduced under lowlight-intensity, and Cyt f reduction following the flash wasrapid, which indicates that the turnover of PS I limits theoverall rate of electron flow. After an increase in the abundanceof PS I, the electron transport recovered from the biased state.(4) The redox steady-state of the Cyt b₆-f complex correlatedwell with the regulation of PS I/PS II while the state of thePQ pool did not. Based on these results, a working model ofthe regulation of assembly of the PS I complex, in which theredox steady-state of the Cyt b₆-f complex is closely relatedto the primary signal, is proposed. (Received August 2, 1990; Accepted December 10, 1990)     

The Supramolecular Organization of Red Algal Vacuole Membrane Visualized by Freeze-fracture

The supramolecular organization of the vacuole membrane (orof the membranes of mucilage sacs) in 27 species of red algaeis studied in replicas of rapidly frozen and fractured cells.Intramembranous particle complexes composed of four particles('tetrads' with average diameters between 8·5 and 14·5have been observed in the protoplasmic fracture (PF) face butmost clearly and more frequently in the exoplasmic fracture(EF) face of the vacuole membrane of all red algae investigated.The tetrads lie individually within the vacuole membrane orform clusters in several species and are randomly distributed.In the species Ceramium diaphanum var. strictum and Laurenciaobtusa the intramembranous particle complexes ('tetrads') havebeen observed both in the EF and PF faces of the vacuole membrane;the 'membrane tetrads' at least as regards these two speciesseem to span both the outer and inner leaflets of the vacuolemembrane ('transmembrane particles'). The occurrence of particletetrads in the plasma membrane is probably due to exocytosiseither of the Golgi vesicles or of the mucilage sacs. Tetradfrequency in the EF face of the vacuole membranes of the investigatedred algae varies between 2 and 87 µm^-2, while that ofsingle particles varies between 102 and 695 µm^-2. ThePF face of the vacuole membrane is characterized by a higherparticle density than the EF face. The particle densities ofthe PF and EF faces of the plasma membrane for a given speciesare higher than those of the corresponding fracture faces ofthe vacuole membrane. Some members of Bangiophycidae bear smallerprotein particles (diameter between 8·5 and 10·5nm) in comparison with those of Florideophycidae (diameter between10·5 and 14·5 nm). It is suggested, based uponthe particle tetrads lying in depressions of the vacuole membraneand the origin of vacuoles (mucilage sacs) from ER, that theparticle tetrads originate from the ER or the Golgi complex.Since vacuoles (mucilage sacs) in red algae, along with theGolgi complex, are involved in the synthesis and export of cellsurface polysaccharides, it could be assumed that the 'membrane-tetrads'within the vacuole membrane represent a membrane-bound multienzymecomplex, participating in the synthesis of amorphous extracellularmatrix polysaccharides.Copyright 1993, 1999 Academic Press Red algae, freeze-fracture, vacuole membrane, mucilage sacs, membrane tetrads, supramolecular organization     

Location of the Electron Accepting Site of a b-Type Cytochrome Oxidase in Purified Chromatophore Membranes and Spheroplast Membrane Vesicles from Photosynthetically Grown Rhodopseudomonas sphaeroides

Purified chromatophore membranes and spheroplast membrane vesicleswere prepared from Rhodopseudomonas sphaeroides by the methodof Michels and Konings (1978). The cytochrome c oxidase activityof the spheroplast membrane vesicles was about 15-fold higheron a bacteriochlorophyll basis than that of the chromatophoremembranes. The cytochrome c oxidase activity of the chromatophoremembranes was greatly stimulated (about 10-fold) by an additionof Triton X-100 (0.1%), but there was less stimulated (about1.5-fold) in the case of spheroplasts. The pH optimum of theoxidase activities of the spheroplast membrane vesicles andof chromatophore membranes treated with 0.1% Triton X-100, andthe salt dependencies of the activity of both preparations werethe same. These results show that the membrane-bound b-type cytochromeoxidase of this bacterium accepts electrons from ferrocytochromec on the periplasmic side of the membrane (on the outer surfaceof the spheroplast membrane vesicles). These results also areconsistent with the fact that cytochrome c₂ is located in theperiplasmic space in this bacterium. (Received January 24, 1984; Accepted April 24, 1984)     

Effects of native and oxidized apolipoprotein A-I on lipid bilayer microviscosity of erythrocyte plasma membrane

Using a pyrene as a fluorescent probe, we investigated the influence of native and oxidized apolipoprotein A-I (apo A-I) and their complexes with tetrahydrocortisol (THC) on the microviscosity of the erythrocyte plasma membrane. The addition of THC to isolated membranes led to a 17% increase in the membrane microviscosity. In contrast, native apo A-I reduced the microviscosity (i.e., increased the fluidity) of the membranes by 15%. A more pronounced increase (by 25%) in the membrane fluidity was found in the presence of the complex of apo A-I with THC. Unlike native apo A-I, oxidized apo A-I and its complex with THC did not change the membrane viscosity. In view of the fact that apo A-I plays an important role in the binding of membrane cholesterol we suggest that the observed increase in the membrane fluidity under the influence of the native apo A-I is associated with the cholesterol efflux from plasma membrane. Oxidative modification of apo A-I likely disturbs the mechanisms of the cholesterol efflux and prevents the decrease in the membrane microviscosity.     

脉冲电场对人红细胞膜结构影响的冷冻断裂研究

对外加脉冲电场处理的人红血球冷冻断裂和蚀刻的复型观察中发现在强电场(3KV/cm)作用下,细胞周围有颗粒状和纤维状结构。结合SDS电泳分析证明了它们是由于在电场作用下,红血球膜的带3蛋白和膜骨架蛋白(血影蛋白)脱出的结果。在强电场作用下,由于膜蛋白和膜骨架蛋白的脱出造成了对细胞膜的损伤,使细胞膜稳定性降低,细胞易变形和形成伪足。由于膜蛋白的脱出,多余的自由脂质进入细胞质内而形成泡状结构。外电场改变了蛋白-蛋白以及蛋白-脂分子间的作用可能是电穿孔的主要机理。本文还对当前公认的冷冻断裂中所观察到的膜中间颗粒的来源提出了疑问,并提出了它们还可能与冰晶有关。而冰晶的形成又与膜的亲水与疏水性有关。     

Expression of protein complexes and individual proteins upon transition of etioplasts to chloroplasts in pea (Pisum sativum)

The protein complexes of pea (Pisum sativum L.) etioplasts,etio-chloroplasts and chloroplasts were examined using 2D BlueNative/SDS–PAGE. The most prominent protein complexesin etioplasts were the ATPase and the Clp and FtsH proteasecomplexes which probably have a crucial role in the biogenesisof etioplasts and chloroplasts. Also the cytochrome b₆f (Cytb₆f) complex was assembled in the etioplast membrane, as wellas Rubisco, at least partially, in the stroma. These complexesare composed of proteins encoded by both the plastid and nucleargenomes, indicating that a functional cross-talk exists betweenpea etioplasts and the nucleus. In contrast, the proteins andprotein complexes that bind chlorophyll, with the PetD subunitand the entire Cyt b₆f complex as an exception, did not accumulatein etioplasts. Nevertheless, some PSII core components suchas PsbE and the luminal oxygen-evolvong complex (OEC) proteinsPsbO and PsbP accumulated efficiently in etioplasts. After 6h de-etiolation, a complete PSII core complex appeared with40% of the maximal photochemical efficiency, but a fully functionalPSII was recorded only after 24 h illumination. Similarly, thecore complex of PSI was assembled after 6 h illumination, whereasthe PSI–light-harvesting complex I was stably assembledonly in chloroplasts illuminated for 24 h. Moreover, a batteryof proteins responsible for defense against oxidative stressaccumulated particularly in etioplasts, including the stromaland thylakoidal forms of ascorbate peroxidase, glutathione reductaseand PsbS.     

Modulation of membrane receptor endocytosis by chemical effectors of membrane fluidity

Several chemical effectors were used to induce changes in spleen B cell membrane fluidity. Membrane fluidity was monitored by fluorescence polarization analysis of the hydrophobic probe 1,6-diphenyl-1,3,5-hexatriene (DPH) and cell viability was checked not to be affected by the treatments. Membrane immunoglobulin (Ig) endocytosis by the living B cells with modified or unmodified membranes was quantitatively measured by flow cytometry, using a previously described method (Métézeau et al., 1982, 1984). The kinetics of endocytosis of membrane Ig was not affected by chemical effectors increasing membrane fluidity. On the contrary, increasing membrane microviscosity resulted in the slowing down and eventually the blocking of membrane Ig endocytosis. It is suggested that a step depending on membrane microviscosity is involved in the process of endocytosis; this step may become rate limiting when membranes are artificially rendered or naturally become (i.e. for pathological or particularly differentiated cells) more viscous.     

Changes in Membrane Fluidity and Protein Composition during Release of Cucumber Seeds from Dormancy by a Higher Temperature Shift

Dormancy of seeds of cucumber (Cucumis sativus L.) was inducedby imbibing in -1.8 MPa polyethylene glycol 6000 (PEG) solutionand pulsing with far red light for 15 min prior to washing anddrying. When re-imbibed with water at 20 °C, dormancy wasbroken by raising the temperature to 30 °C for 6 h. Thistreatment was also effective when -0.9 MPa PEG was present duringre-imbibition and high temperature. Seeds with broken dormancywere found to germinate in water over a smaller temperaturerange than seeds in which dormancy had not been induced. Whenthe duration of the temperature shift to 30 °C was varied,germination percentage increased from 7 to 60% after 6 h, butlonger exposures up to 12 h had no further promoting effect.The time course of germination after transfer to water following6 h at 30 °C in PEG showed piercing of the perisperm-endospermenvelope after 9–12 h and radicle protusion after 12–15h. If PEG was retained after high temperature treatment no visiblegermination was observed. Thus, to study membrane fluidity andthe protein content associated with germination, seeds weresampled 9 h after high temperature treatment. To study the germinablebut not germinating state, seed held in PEG for 9 h rather thanin water was used. Dormant seed was sampled before the hightemperature treatment. Membrane fluidity was assessed usingfluorescence polarization of membrane fractions treated withDPH (1,6-diphenyl-1,3,5-hexatriene) or its derivatives. Membraneproteins were compared using one-dimensional SDS-PAGE electrophoresis.Intracellular membrane fluidity was not increased in the transitionfrom the dormant to germinable state, but did increase in thetransition to germination. There were no detected changes inintracellular membrane proteins during either transition. Inplasma membrane fractions, fluidity increased during both transitions,while a marked increase in 21, 18 and 17 kD proteins was observedin the transition from germinable to germinating state. Thusmodification of plasma membrane fluidity rather than changesin protein profile is associated with the high temperature releaseof cucumber seeds from dormancy. Copyright 2000 Annals of BotanyCompany     

Dimethylnitrosamine inhibits the glucagon-stimulated adenylate cyclase activity of rat liver plasma membranes and decreases plasma membrane fluidity

The effect of the hepatocarcinogen dimethylnitrosamine on rat liver plasma membrane adenylate cyclase activity and lipid fluidity was assessed. Glucagon-stimulated adenylate cyclase activity exhibited a complex response to increasing concentrations of dimethylnitrosamine, whereas fluoride-stimulated adenylate cyclase activity was progressively inhibited. Maximal inhibitory effects were observed at a concentration of 15 mM in both cases. The activity of detergent-solubilized adenylate cyclase was unaffected by dimethylnitrosamine. ESR analysis using a fatty acid spin probe showed that dimethylnitrosamine produced a marked, dose-dependent reduction in the fluidity of the plasma membrane with a maximal effect occurring at 20 mM. Dimethylnitrosamine also elevated the temperature at which the lipid phase separation occurred in rat liver plasma membranes, from 28 degrees C to 31 degrees C. The non-carcinogenic but structurally similar compound, dimethylamine hydrochloride neither inhibited adenylate cyclase nor decreased plasma membrane fluidity. It is suggested that the decrease in membrane fluidity, induced by dimethylnitrosamine, via its effects on membrane fluidity, could influence plasma membrane function and cellular regulation.     

Membrane-associated proteins affect the formation of filipin-cholesterol complexes in viral membranes

The presence and distribution of cholesterol in biological membranes can be visualized by complex formation with the polyene antibiotic filipin after or during fixation with glutaraldehyde. In the envelopes of budding and immature retroviruses no filipin-cholesterol complexes are formed, but in the plasma membrane of host cells and in the envelopes of mature viruses filipin-cholesterol complexes are easily detected. However, after treatment of glutaraldehyde-fixed cells with pepsin, the presence of cholesterol in the envelopes of budding and immature viral particles could also be demonstrated. This indicates that in these structures the reaction of cholesterol with filipin is inhibited by proteins associated with the cholesterol-containing membrane. Treatment of fixed cells with trypsin, and of unfixed cells with cytochalasin B (CB) had no effect on detectability of cholesterol in these structures. On no occasion were cholesterol-filipin complexes formed in coated pits. The present findings call for caution when interpretating data on absence of filipincholesterol complexes in those membrane domains that are characterized by the presence of closely associated proteins.     

Metabolic control of the membrane fluidity in Bacillus subtilis during cold adaptation

Membrane fluidity adaptation to the low growth temperature in Bacillus subtilis involves two distinct mechanisms: (1) long-term adaptation accomplished by increasing the ratio of anteiso- to iso-branched fatty acids and (2) rapid desaturation of fatty acid chains in existing phospholipids by induction of fatty acid desaturase after cold shock. In this work we studied the effect of medium composition on cold adaptation of membrane fluidity. Bacillus subtilis was cultivated at optimum (40 degrees C) and low (20 degrees C) temperatures in complex medium with glucose or in mineral medium with either glucose or glycerol. Cold adaptation was characterized by fatty acid analysis and by measuring the midpoint of phospholipid phase transition T(m) (differential scanning calorimetry) and membrane fluidity (DPH fluorescence polarization). Cells cultured and measured at 40 degrees C displayed the same membrane fluidity in all three media despite a markedly different fatty acid composition. The T(m) was surprisingly the highest in the case of a culture grown in complex medium. On the contrary, cultivation at 20 degrees C in the complex medium gave rise to the highest membrane fluidity with concomitant decrease of T(m) by 10.5 degrees C. In mineral media at 20 degrees C the corresponding changes of T(m) were almost negligible. After a temperature shift from 40 to 20 degrees C, the cultures from all three media displayed the same adaptive induction of fatty acid desaturase despite their different membrane fluidity values immediately after cold shock.     

Structure and Function of the Golgi Complex in Rice Cells: Characterization of Golgi Membrane Glycoproteins

The structure and synthesis of the saccharide chains of Golgimembrane glycoproteins in suspension-cultured rice (Oryza sativaL.) cells were studied. Peanut lectin (PNA) and Ulex europaeuslectin-I (UEA-I) have high affinity for typical O-linked saccharidechains and both recognized the saccharide chains of rice Golgimembrane glycoproteins. These glycoproteins were also sensitiveto alkali and to O-glycanase. These results indicate that theGolgi membrane glycoproteins have O-linked saccharide chains.Brefeldin A, a specific inhibitor of Golgi-mediated secretion,induced morphological changes in Golgi complexes and preventedthe synthesis of the saccharide chains of the membrane glycoproteinsthat could be recognized by PNA and UEA-I. These glycoproteinswere typically localized in all compartments of the Golgi complex.Monensin can arrest the transport of secretory proteins frommedial to trans Golgi compartments but did not affect the formationand localization of the Golgi membrane glycoproteins. Tunicamycin,an inhibitor of the synthesis of N-linked saccharide chains,did not inhibit the synthesis of the saccharide chains of theseGolgi membrane glycoproteins. These results strongly suggestthat the synthesis of O-linked saccharide chains of Golgi membraneglycoproteins is initiated in the cis Golgi compartment. (Received September 24, 1992; Accepted June 4, 1993)     

Assembly of Cellulose Synthesizing Complexes on the Plasma Membrane of Boodlea coacta

The assembly of cellulose synthesizing complexes (terminal complexes,TCs) on the plasma membrane of Boodlea coacta was investigatedduring the formation of both the matrix-rich layer (MRL) andfibril-rich layers (FRLs) of cell walls. The TCs appeared tobe located mostly within the outer leaflet of the plasma membrane,and were observed as elliptical protrusions consisting of manyparticles of about 9 nm in diameter. Their length varied from100 to 500 nm (average, 220 nm) during MRL formation and from100 to 860 nm (average, 360 nm) during FRL formation. A correlationwas found between the length of TCs and the microfibril widthin both MRL and FRL. On the E-face of the plasma membrane, numerous round protrusions(30–130 nm in diameter), consisting of many particles,8–10 nm in diameter, were also present. Their densitywas greater during FRL formation than during MRL formation.Some of these structures larger than 100 nm were associatedwith microfibril impressions and some appeared to be bound tothe TCs. These protrusions increased in number with Calcofluortreatment but decreased in number when the dye was removed fromthe culture medium. Thus, the TCs may be assembled from massesof particles aggregated on the outer surface of the plasma membrane,and may grow longer by incorporation of these masses. The appearanceof the longer TCs during FRL formation is probably due to thegreater density of these masses. (Received May 1, 1985; Accepted August 16, 1985)     

Regulation of the Stoichiometry of Thylakoid Components in the Photosynthetic System of Cyanophytes: Model Experiments Showing that Control of the Synthesis or Supply of Chl a can Change the Stoichiometric Relationship between the Two Photosystems

Regulation of the assembly of the photosystem I (PS I) complexin response to the light regime in the photosynthetic systemof cyanophytes was studied in Synechocystis PCC 6714. The relationshipbetween the assembly of the PS I complex and synthesis of Chla was examined by model experiments in which synthesis of Chla was controlled by two inhibitors, gabaculine (GAB) and 2,2'-dipyridyl(DP). Both inhibitors caused a change to a lower ratio of PSI to PS II even under light that normally induces a high ratioof PS I to PS II. The change in stoichiometry induced by theseinhibitors was suppressed when protein synthesis was inhibitedby chloram-phenicol, similarly to the change in the stoichiometryinduced by light that excites mainly PS I (PS I light). Comparisonof the levels of PS I, PS II and Cyt b₆-f complexes per cellindicated that a selective suppression of the assembly of thePS I complex was induced by the inhibitors: the stoichiometricrelationship among PS I, PS II and Cyt b₆-f complexes was identicalto that induced by PS I light or white light of high intensity.GAB induced a decrease in size of the phycobilisome also, whileDP did not, similarly to PS I light. The results indicate thatthe ratio of PS I to PS II can be changed by the control ofsynthesis of Chl a. They also suggest that control of the synthesisor supply of Chl a probably exerted at site(s) in or after theprocess of the Mg-protoporphyrin branch, is involved in themechanism of regulation of the assembly of the PS I complexin cyanophytes. (Received September 7, 1989; Accepted November 20, 1989)     

Membrane structure and surface coat of Entamoeba histolytica. Topochemistry and dynamics of the cell surface: cap formation and microexudate

Treatment of living entamoeba histolytica cells with low concentrations of concanavalin A (con A) and peroxidase results in redistribution of the plasma membrane con A receptors to one pole of the cell where a morphologically distinct region--the uroid--is formed. Capping of con A receptors is not accompanied by parallel accumulation of ruthenium red-stainable components. In capped cells, the pattern of distribution of acidic sites ionized at pH 1.8 (labeled by colloidal iron) at the outer surface and of membrane particles (integral membrane components revealed by freeze-fracture) is not altered over the uroid region. Cytochemistry of substrate-attached microexudate located in regions adjacent to E. histolytica cells demonstrates the presence of con A binding sites and ruthenium red- and alcian blue-stainable components and the absent of colloidal iron binding sites. In a previous report we demonstrated that glycerol-induced aggregation of the plasma membrane particles is accompanied by a discontinuous distribution of colloidal iron binding sites, while con A receptors and acidic sites ionized at pH 4.0 remain uniformly distributed over the cell surface. Taken together, our experiments show that, in E. histolytica cells, peripheral membrane components may move independently of integral components and, also, that certain surface determinants may redistribute independently of others. These results point to the complexity of the membrane structure-cell surface relationship in E. histolytica plasma membranes relative to the membrane of the erythrocyte ghost where integral components (the membrane-intercalated particles) contain all antigens, receptors, and anionic sites labeled so far. We conclude that fluidity of integral membrane components (integral membrane fluidity) cannot be inferred from the demonstration of the mobility of surface components nor, conversely, can the fluidity of peripheral membrane components (peripheral membrane fluidity) be assumed from demonstration of the mobility of integral membrane components.     

Chlorophyll-Protein Complexes in Salix sp. 'Aquatica Gigantea' under Strong and Weak Light I. Spectral Characterization of the Chlorophyll-Protein Complexes

The distribution of chlorophyll in the chlorophyll-protein complexeswas studied in Salix sp. ‘aquatica gigantea’ grownunder high and low irradiance. The chlorophyll- containing bandsthat could be separated by SDS-polyacrylamide gel electrophoresisin strong and weak light numbered 9 to 13 and 9 to 11, respectively.In strong light the following bands were separated, in the orderof the highest to the lowest molecular weight: one to two chlorophylla/b-protein complexes, three to four chlorophyll a-containingbands similar to the P700-chlorophyll a-protein complex (CPIand its oligomers), three oligomers of the light-harvestingchlorophyll a/b-protein complex (LHCP^***, LHCP^**, LHCP^*), twochlorophyll a-protein complexes (CPa₂ and CPa₁), the light-harvestingchlorophyll a/b-protein complex (LHCP) and the protein freepigment (FP). In weak light the same chlorophyll-containingbands were separated with the exception that no high molecularweight chlorophyll a/b-protein complexes could be observed.In strong light the CPI complexes were the largest structuralcomponent of the chloroplast lamellae. In weak light the LHCPcomplexes together contributed the major proportion of the totalchlorophyll. The increase in the chlorophyll associated withthe LHCP complex was possibly caused by reorganization of thelamellar structure or by increased synthesis of the LHCP^** complex,which appeared to be a labile complex in weak light. (Received February 1, 1982; Accepted May 10, 1982)     

NAD (P)H-Duroquinone Reductase in the Plant Plasma Membrane

The intracellular distribution of NADPH- and NADH-dependentduroquinone reductase (NAD (P)H-DQR) from etiolated zucchinihypocotyls (Cucurbita pepo L.) was investigated. About 80% ofthis enzyme is in the supernatant fraction and is probably cytosolic.Particulate NAD (P)H-DQR was largely (42%) found in associationwith the plasma membrane and was strongly stimulated by TX100.Another 33% of NAD (P)H-DQR was associated with mitochondria,and minor fractions with the endoplasmic reticulum (8%) andother particles. All these fractions were little or not stimulatedby TX100. The distribution of detergent-activated NAD (P)H-DQRis thus distinct from microsomal NADH- and NADPH-CCR. The plasma membrane was purified from microsomal fractions bymetrizamide plus sucrose density gradient centrifugation orby PEG/dextran phase partitioning. Both types of particle preparationspeaked at a density (d) of 1.165 g cm^–3 in sucrose gradientsand contained substantial TX100-sensitive NADH-DQR, TX100-stimulatedNAD (P)H-DQR, together with traces of NADH-CCR and trapped ‘soluble’enzyme (MDH, NADP-malic enzyme) activities. In isopycnic gradientsof unfractionated microsomes, however, trapped enzymes peakedat d 1.155 whereas NAD (P)H-DQR peaked at d 1.165 and GSII atd 1.170, probably revealing plasma membrane heterogeneity. Furtherevidence of heterogeneity was provided by fractionation of plasmamembrane vesicles on dextran step-gradients. Most of the trapped MDH was released to the supernatant by sonicationor treatment with 0.0125% TX100. Under these conditions mostof the NAD (P)H-DQR sedimented with the membranes. It is concludedthat NAD (P)H-DQR is bound to the inside of plasma membranevesicles, but a fraction (7 to 31%) may be ‘soluble’and sequestered within the vesicle lumen. Part of the detergent-sensitiveNADH-DQR may be externally bound and accessible to non-permeatingsubstrates. Key words: Cucurbita, NAD (P)H-quinone reductase, plasma membrane