The role of ribosomal proteins in in vitro ribosome-membrane interactions]

The in vitro binding of total ribosomal proteins with rough endoplasmic membranes, from which 70% of ribosomes are eliminated by EDTA (ME) is studied. It is found that in conditions of specific interaction of ribosomes with membranes about 75% of total ribosomal proteins are bound with ME. Membranes, heterogenous in their content (different protein/lipid ratio), became homogenous in their buyoant density after the binding with proteins. The ability of membrane-ribosomal protein complex to bind ribosomes is not decreased, as it can be expected, but is considerablly increased, thus indicating on a non-specific character of ribosome binding. Ribosomal subunits lacking about half of structural protein are capable to bind with ribosome-binding membrane receptors and with some additional sites. This binding is also non-specific, because the binding efficiency of large and small subunits is the same.     

The binding of ribosomal subunits to endoplasmic reticulum membranes

The binding of ribosomes and ribosomal subunits to endoplasmic reticulum preparations of mouse liver was studied. (1) Membranes prepared from rough endoplasmic reticulum by preincubation with 0.5m-KCl and puromycin bound 60-80% of added 60S subunits and 10-15% of added 40S subunits. Membranes prepared with pyrophosphate and citrate showed less clear specificity for 60S subunits particularly when assayed at low ionic strengths. (2) Ribosomal 40S subunits bound efficiently to membranes only in the presence of 60S subunits. The reconstituted membrane-60S subunit-40S subunit complex was active in synthesis of peptide bonds. (3) No differences in binding to membranes were seen between subunits derived from free and from membrane-bound ribosomes. (4) It is concluded that the binding of ribosomes to membranes does not require that they be translating a messenger RNA, and that the mechanism whereby bound and free ribosomes synthesize different groups of proteins does not depend on two groups of ribosomes that differ in their ability to bind to endoplasmic reticulum.     

Study of electrophoretic mobility of cellular membranes isolated from rat liver

Plasma membranes as well as mitochondrial and microsomal subfractions were subjected to zone electrophoresis. Treatment with neuraminidase, phospholipase A or C does not influence the movement of plasma membranes and smooth microsomes. Trypsin increases mobility of plasma membranes and smooth by about 20%, and further treatment with phospholipase C decreases mobility of plasma membranes, total smooth and smooth I microsomes, which, however, is not the case with smooth II microsomes. Low concentrations of trypsin also solubilize enzyme proteins of smooth microsomes from phenobarbital-treated rat liver, but electrophoretic mobility is not increased, indicating structural differences in induced membranes. The mobility of the outer and inner mitochondrial membranes is significantly higher than that of submitochondrial particles. For microsomes the negative surface charge density occurs in the decreasing order of: ribosomes — rough — smooth I — smooth II. A 10 mM CsCl gradient decreases the mobility of rough microsomes by 40% and of ribosomes by 20% but has no effect on total smooth microsomes. On the other hand, 5 mM MgCl₂ decreased the mobility of all three fractions. EDTA-treated rough and EDTA-treated smooth microsomes have the same electrophoretic mobilities. However, the mobilities of non-treated rough and smooth microsomes differ significantly from each other.     

RIBOSOME-MEMBRANE INTERACTION : Nondestructive Disassembly of Rat Liver Rough Microsomes into Ribosomal and Membranous Components

In a medium of high ionic strength, rat liver rough microsomes can be nondestructively disassembled into ribosomes and stripped membranes if nascent polypeptides are discharged from the bound ribosomes by reaction with puromycin. At 750 mM KCl, 5 mM MgCl₂, 50 mM Tris·HCl, pH 7 5, up to 85% of all bound ribosomes are released from the membranes after incubation at room temperature with 1 mM puromycin. The ribosomes are released as subunits which are active in peptide synthesis if programmed with polyuridylic acid. The ribosome-denuded, or stripped, rough microsomes (RM) can be recovered as intact, essentially unaltered membranous vesicles Judging from the incorporation of [³H]puromycin into hot acid-insoluble material and from the release of [³H]leucine-labeled nascent polypeptide chains from bound ribosomes, puromycin coupling occurs almost as well at low (25–100 mM) as at high (500–1000 mM) KCl concentrations. Since puromycin-dependent ribosome release only occurs at high ionic strength, it appears that ribosomes are bound to membranes via two types of interactions: a direct one between the membrane and the large ribosomal subunit (labile at high KCl concentration) and an indirect one in which the nascent chain anchors the ribosome to the membrane (puromycin labile). The nascent chains of ribosomes specifically released by puromycin remain tightly associated with the stripped membranes. Some membrane-bound ribosomes (up to 40%) can be nondestructively released in high ionic strength media without puromycin; these appear to consist of a mixture of inactive ribosomes and ribosomes containing relatively short nascent chains. A fraction (~15%) of the bound ribosomes can only be released from membranes by exposure of RM to ionic conditions which cause extensive unfolding of ribosomal subunits, the nature and significance of these ribosomes is not clear.     

Effects of phenobarbital on protein synthesis and polysome levels in rat liver.

Administration of phenobarbital to rats increases the rate of synthesis of certain microsomal drug-metabolizing enzymes in a selective manner and promotes proliferation of smooth endoplasmic reticulum in the liver. Phenobarbital increased a number of factors by which protein synthesis could be enhanced in the liver. It produced a 30% increase in the amount of ribosomes and mRNA per cell. The proportion of ribosomes associated with polysomes was increased by 5-10% over normal liver. There was a 10-30% increase in the rate of ploypeptide elongation and a small increase or no change in polysome size, indicating that the rate of polypeptide initiation was increased proportionately. The product of these effects accounts for the 1.5-fold increase in the rate of total protein synthesis previously reported. The average polysome size, and the size of free polysomes in particular, was maintained when actinomycin D was administered to phenobarbital-pretreated rats, suggesting that the rate of mRNA degradation was decreased selectively. Phenobarbital did not, however, affect the distribution of ribosomes between the free and membrane-bound states or the activity of ribonucleases associated with isolated free and bound polysomes. Thus, we conclude that phenobarbital stimulates protein synthesis by expanding the mRNA pool, at least partially through effects on mRNA degradation, and by augmenting the rate of mRNA translation.     

Characterization of secretory protein translocation: ribosome-membrane interaction in endoplasmic reticulum

Secretory proteins are synthesized on ribosomes bound to the membrane of the endoplasmic reticulum (ER). After the selection of polysomes synthesizing secretory proteins and their direction to the membrane of the ER via signal recognition particle (SRP) and docking protein respectively, the polysomes become bound to the ER membrane via an unknown, protein-mediated mechanism. To identify proteins involved in protein translocation, beyond the (SRP-docking protein-mediated) recognition step, controlled proteolysis was used to functionally inactivate rough microsomes that had previously been depleted of docking protein. As the membranes were treated with increasing levels of protease, they lost their ability to be functionally reconstituted with the active cytoplasmic fragment of docking protein (DPf). This functional inactivation did not correlate with a loss of either signal peptidase activity, nor with the ability of the DPf to reassociate with the membrane. It did correlate, however, with a loss of the ability of the microsomes to bind ribosomes. Ribophorins are putative ribosome-binding proteins. Immunoblots developed with monoclonal antibodies against canine ribophorins I and II demonstrated that no correlation exists between the protease-induced inability to bind ribosomes and the integrity of the ribophorins. Ribophorin I was 85% resistant and ribophorin II 100% resistant to the levels of protease needed to totally eliminate ribosome binding. Moreover, no direct association was found between ribophorins and ribosomes; upon detergent solubilization at low salt concentrations, ribophorins could be sedimented in the presence or absence of ribosomes. Finally, the alkylating agent N-ethylmaleimide was shown to be capable of inhibiting translocation (beyond the SRP-docking protein-mediated recognition step), but had no affect on the ability of ribosomes to bind to ER membranes. We conclude that potentially two additional proteinaceous components, as yet unidentified, are involved in protein translocation. One is protease sensitive and possibly involved in ribosome binding, the other is N-ethylmaleimide sensitive and of unknown function.     

Membrane-bound ribosomes of myeloma cells. III. The role of the messenger RNA and the nascent polypeptide chain in the binding of ribosomes to membranes

Mild ribonuclease treatment of the membrane fraction of P3K cells released three types of membrane-bound ribosomal particles: (a) all the newly made native 40S subunits detected after 2 h of [3H]uridine pulse. Since after a 3-min pulse with [35S]methionine these membrane native subunits appear to contain at least sevenfold more Met-tRNA per particle than the free native subunits, they may all be initiation complexes with mRNA molecules which have just become associated with the membranes; (b) about 50% of the ribosomes present in polyribosomes. Evidence is presented that the released ribosomes carry nascent chains about two and a half to three times shorter than those present on the ribosomes remaining bound to the membranes. It is proposed that in the membrane-bound polyribosomes of P3K cells, only the ribosomes closer to the 3' end of the mRNA molecules are directly bound, while the latest ribosomes to enter the polyribosomal structures are indirectly bound through the mRNA molecules; (c) a small number of 40S subunits of polyribosomal origin, presumably initiation complexes attached at the 5' end of mRNA molecules of polyribosomes. When the P3K cells were incubated with inhibitors acting at different steps of protein synthesis, it was found that puromycin and pactamycin decreased by about 40% the proportion of ribosomes in the membrane fraction, while cycloheximide and anisomycin had no such effect. The ribosomes remaining on the membrane fraction of puromycin-treated cells consisted of a few polyribosomes, and of an accumulation of 80S and 60S particles, which were almost entirely released by high salt treatment of the membranes. The membrane-bound ribosomes found after pactamycin treatment consisted of a few polyribosomes, with a striking accumulation of native 60S subunits and an increased number of native 40S subunits. On the basis of the observations made in this and the preceding papers, a model for the binding of ribosomes to membranes and for the ribosomal cycle on the membranes is proposed. It is suggested that ribosomal subunits exchange between free and membrane-bound polyribosomes through the cytoplasmic pool of free native subunits, and that their entry into membrane-bound ribosomes is mediated by mRNA molecules associated with membranes.     

On the interactions of catalase with subcellular structure

The interaction of mouse liver catalase with subcellular membranes was studied, and an ionic interaction with a variety of membranes, including those derived from the microsomes, was observed. The interaction with microsomal membranes was found to be abolished by pre-treatment of catalase with neuraminidase, indicating a functional significance for catalase-bound sialic acid. Catalase activity was found to be enhanced when bound to membranes, and evidence for a weak association of catalase with peroxisomal structure in mouse liver was also obtained. It is concluded that mouse liver catalase has a capacity to bind to a variety of subcellular membranes in vivo and that this interaction may be consistent with a general protective role for the enzyme, as well as being compatible with a model of peroxisomal biogenesis which involves the interaction of catalase with microsomal membranes.Abbreviations LGF Large Granule Fraction     

Study of electrophoretic mobility of cellular membranes isolated from rat liver.

Plasma membranes as well as mitochondrial and microsomal subfractions were subjected to zone electrophoresis. Treatment with neuraminidase, phospholipase A or C does not influence the movement of plasma membranes and smooth microsomes. Trypsin increases mobility of plasma membranes and smooth by about 20%, and further treatment with phospholipase C decreases mobility of plasma membranes, total smooth and smooth I microsomes, which, however, is not the case with smooth II microsomes. Low concentrations of trypsin also solubilize enzyme proteins of smooth microsomes from phenobarbital-treated rat liver, but electrophoretic mobility is not increased, indicating structural differences in induced membranes. The mobility of the outer and inner mitochondrial membranes is significantly higher than that of submitochondrial particles. For microsomes the negative surface charge density occurs in the decreasing order of: ribosomes--rough--smooth I--smooth II. A 10 mM CsCl gradient decreases the mobility of rough microsomes by 40% and of ribosomes by 20% but has no effect on total smooth micromes. On the other hand, 5mM MgCl2 decreased the mobility of all three fractions. EDTA-treated rough and EDTA-treated smooth microsomes have the same electrophoretic mobilities. However, the mobilities of non-treated rough and smooth microsomes differ significantly from each other.     

Proteins of rough microsomal membranes related to ribosome binding. II. Cross-linking of bound ribosomes to specific membrane proteins exposed at the binding sites

Two proteins (ribophorins I and II), which are integral components of rough microsomal membranes and appear to be related to the bound ribosomes, were shown to be exposed on the surface of rat liver rough microsomes (RM) and to be in close proximity to the bound ribosomes. Both proteins were labeled when intact RM were incubated with a lactoperoxidase iodinating system, but only ribophorin I was digested during mild trypsinization of intact RM. Ribophorin II (63,000 daltons) was only proteolyzed when the luminal face of the microsomal vesicles was made accessible to trypsin by the addition of sublytical detergent concentrations. Only 30--40% of the bound ribosomes were released during trypsinization on intact RM, but ribosome release was almost complete in the presence of low detergent concentrations. Very low glutaraldehyde concentrations (0.005--0.02%) led to the preferential cross-linking of large ribosomal subunits of bound ribosomes to the microsomal membranes. This cross-linking prevented the release of subunits caused by puromycin in media of high ionic strength, but not the incorporation of [3H]puromycin into nascent polypeptide chains. SDS-acrylamide gel electrophoresis of cross-linked samples a preferential reduction in the intensity of the bands representing the ribophorins and the formation of aggregates which did not penetrate into the gels. At low methyl-4-mercaptobutyrimidate (MMB) concentrations (0.26 mg/ml) only 30% of the ribosomes were cross-linked to the microsomal membranes, as shown by the puromycin-KCl test, but membranes could still be solubilized with 1% DOC. This allowed the isolation of the ribophorins together with the sedimentable ribosomes, as was shown by electrophoresis of the sediments after disruption of the cross-links by reduction. Experiments with RM which contained only inactive ribosomes showed that the presence of nascent chains was not necessary for the reversible cross-linking of ribosomes to the membranes. These observations suggest that ribophorins are in close proximity to the bound ribosomes, as may be expected from components of the ribosome-binding sites.     

RIBOSOMES BOUND TO CHLOROPLAST MEMBRANES IN CHLAMYDOMONAS REINHARDTII

The amount of chloroplast ribosomal RNAs of Chlamydomonas reinhardtii which sediment at 15,000 g is increased when cells are treated with chloramphenicol. Preparations of chloroplast membranes from chloramphenicol-treated cells contain more chloroplast ribosomal RNAs than preparations from untreated cells. The membranes from treated cells also contain more ribosome-like particles, some of which appear in polysome-like arrangements. About 50% of chloroplast ribosomes are released from membranes in vitro as subunits by 1 mM puromycin in 500 mM KCl. A portion of chloroplast ribosomal subunits is released by 500 mM KCl alone, a portion by 1 mM puromycin alone, and a portion by 1 mM puromycin in 500 mM KCl. Ribosomes are not released from isolated membranes by treatment with ribonuclease. Membranes in chloroplasts of chloramphenicol-treated cells show many ribosomes associated with membranes, some of which are present in polysome-like arrangements. This type of organization is less frequent in chloroplasts of untreated cells. Streptogramin, an inhibitor of initiation, prevents chloramphenicol from acting to permit isolation of membrane-bound ribosomes. Membrane-bound chloroplast ribosomes are probably a normal component of actively growing cells. The ability to isolate membrane-bound ribosomes from chloramphenicol-treated cells is probably due to chloramphenicol-prevented completion of nascent chains during harvesting of cells. Since chloroplasts synthesize some of their membrane proteins, and a portion of chloroplast ribosomes is bound to chloroplast membranes through nascent protein chains, it is suggested that the membrane-bound ribosomes are synthesizing membrane protein.     

Binding of ribosomes to the rough endoplasmic reticulum mediated by the Sec61p-complex

The cotranslational translocation of proteins across the ER membrane involves the tight binding of translating ribosomes to the membrane, presumably to ribosome receptors. The identity of the latter has been controversial. One putative receptor candidate is Sec61 alpha, a multi- spanning membrane protein that is associated with two additional membrane proteins (Sec61 beta and gamma) to form the Sec61p-complex. Other receptors of 34 and 180 kD have also been proposed on the basis of their ability to bind at low salt concentration ribosomes lacking nascent chains. We now show that the Sec61p-complex has also binding activity but that, at low salt conditions, it accounts for only one third of the total binding sites in proteoliposomes reconstituted from a detergent extract of ER membranes. Under these conditions, the assay has also limited specificity with respect to ribosomes. However, if the ribosome-binding assay is performed at physiological salt concentration, most of the unspecific binding is lost; the Sec61p- complex then accounts for the majority of specific ribosome-binding sites in reconstituted ER membranes. To study the membrane interaction of ribosomes participating in protein translocation, native rough microsomes were treated with proteases. The amount of membrane-bound ribosomes is only slightly reduced by protease treatment, consistent with the protease-resistance of Sec61 alpha which is shielded by these ribosomes. In contrast, p34 and p180 can be readily degraded, indicating that they are not essential for the membrane anchoring of ribosomes in protease-treated microsomes. These data provide further evidence that the Sec61p-complex is responsible for the membrane- anchoring of ribosomes during translocation and make it unlikely that p34 or p180 are essential for this process.     

Relative susceptibilities to neuraminidase of the glycoproteins of the human erythrorcyte

Release of sialic acid from the glycoproteins of the normal human erythrocyte surface by neuraminidase was investigated. The glycoproteins of the membrane were separated by electrophoresis in sodium dodecylsulfate polyacrylamide gels. Sialic acid was determined in the sliced gel by a modification of the 2-thiobarbituric acid method, revealing three sialic acid-containing glycoproteins. Treatment of intact erythrocytes with neuraminidase to remove varying amounts of sialic acid indicates that all the glycoproteins are essentially equally accessible to the neuraminidase when 20%–60% of the sialic acid is removed. Similar but not quite identical results were obtained with isolated erythrocyte membranes.Treatment of intact cells with the lectins concanavalin A or phytohemagglutinin-P resulted in shielding of about 25% and 50%, respectively, of the sialic acid from neuraminidase. Concanavalin A blocked sialic acid release over long time periods and with high concentrations of neuraminidase. In contrast, the sialic acid shielding by phytohemagglutinin-P can be overcome by high concentrations of neuraminidase. Both lectins were found to shield the various glycoproteins selectively, with different patterns of shielding. Wheat germ agglutinin exhibited no detectable effect on the susceptibility of the erythrocyte sialic acid to neuraminidase.     

Activity of Thylakoid-bound Ribosomes in Pea Chloroplasts

Pea (Pisum sativum) chloroplast thylakoid membranes were prepared by washing in hypotonic buffers. These membranes contained bound ribosomes which were active in protein synthesis when supplemented with soluble components from a strain of Escherichia coli low in ribonuclease. After dissolving the membranes by Triton and purification of the ribosomes, sucrose density gradient profiles indicated the presence of polysomal material as well as monomeric ribosomes. Most of the products of protein synthesis remained associated with the thylakoid membranes even after ribosomes were removed completely by high salt concentrations in the absence of Mg²⁺. Of the newly formed products, 50% could be digested by pronase, while the remainder were protected by their association with the thylakoid membranes. The products are likely to be a mixture of intrinsic and extrinsic membrane proteins, with only the former completely protected by the membranes from attack by proteases.     

In vitro binding of 70S ribosomes to membrane structures of Escherichia coli

It was found that the maximal disattachment of the ribosomes from the membrane structures is observed upon their treatment with 10 mM tris-HCl buffer, pH 7.5, containing 250 mM sucrose, 750 mM KCl, 5 mM magnesium acetate and 1 mM EDTA or puromycin. The most effective attachment of ribosomes to the membrane occurs in 10 mM tris-HCl buffer, pH 7.5, containing 5% sucrose and Mg2+. The increase of Mg2+ concentration in the medium from 0.5 mM up to 1 mM results in a 2-fold increase of the ribosomes bound to the membranes. The concentration of the ribosomal material involved in the reaction is very essential for ribosome binding to the membranes. The amount of ribosomes bound to the membranes increases proportionally to the increase of the ribosome concentration in the reaction mixture.     

Bound Ribosomes of Pea Chloroplast Thylakoid Membranes: Location and Release in Vitro by High Salt, Puromycin, and RNase

The mode of attachment of 70S ribosomes to thylakoid membranes from pea leaves was studied by determining the proportion of the bound RNA which was released by various incubation conditions. The results supported a model in which several classes of bound ribosomes could be distinguished: (a) very tightly bound, not released by any conditions yet tested (20% of the total); (b) monomeric ribosomes attached by electrostatic interaction with the membranes (30 to 40% of the total) and released by high salt; and (c) polysomes, with some of the ribosomes attached by a combination of electrostatic interactions and insertion of the nascent polypeptide chain into the membrane. These required a combination of puromycin and high salt for release. Other ("hanging") ribosomes of the polysomes were inferred to be attached through mRNA but not actually attached to the membranes directly; they could be released by RNase under low salt conditions, as well as by puromycin plus high salt.To obtain these results, chloroplasts had to be prepared in media containing 0.2 molar Tris at pH 8.5. Using Tricine buffers at pH 7.5 yielded thylakoid membranes whose ribosomes were removed almost completely by high salt alone; these showed no response to puromycin. However, pH 7.5 had to be used in all cases for ribosome dissociation in high salt media, as the ribosome structure appeared to be degraded by high salt at pH 8.5, and release then occurred without the need for puromycin.The kinetics of ribosome release by high salt showed a rapid initial phase with a half-life of 20 seconds. The extent of release by high salt was very dependent on the temperature of the incubation. Plotting the data according to the Arrhenius interpretation shows a significant break at about 15 C, with apparent activation energy of 20 kilocalories per mole below that temperature and 5 kilocalories per mole above that temperature. This result suggests that membrane fluidity might be an important factor permitting release of ribosomes under high salt conditions.Electron microscope pictures of the washed thylakoids showed polysomes closely associated with the outer membranes of grana stacks, and with the stroma lamellae. Following digitonin treatment of the membranes and centrifugation, fractions enriched in Photosystem I and presumed stroma lamellae were also enriched in bound RNA.     

Free and membrane-bound chloroplast polyribosomes Chlamydomonas reinhardtii.

Over half of the chloroplast ribosomes isolated from growing cultures of Chlamydomonas reinhardtii are bound to chloroplast thylakoid membranes if completion of nascent polypeptide chains is prevented by chloramphenicol. The free chloroplast ribosomes are recovered in homogenate supernatants, and presumably originate from the chloroplast stroma. Only about 10% of these free chloroplast ribosomes are polyribosomes, even under conditions when 70% of free cytoplasm ribosomes are recovered as polyribosomes. The nonionic detergent Nonidet P-40 liberates atypical polyribosomes (Type I), from membranes, which require both ribonuclease and proteases for complete conversion to monomeric ribosomes. Thus Type I particles are held together by mRNA but are also held together by peptide bonds. These Type I polyribosomes probably are not bound to intact membrane, but might be bound to some protein-containing sub-membrane particle. The Type I polyribosomes are dissociated to ribosomal subunits by puromycin and high salt, and contained 0.2 to 1 nascent chain per ribosome. If membranes are treated with Nonidet and proteases at the same time, polyribosomes which are digested to monomeric ribosomes by ribonuclease alone (Type II) are obtained. Type II polyribosomes are smaller than Type I, and probably represent the true size distribution of polyribosomes on the membranes. At least 50% of the membrane-bound ribosomes are polyribosomes, since that much membrane bound chloroplast RNA is recovered as Type I or Type II polyribosomes.     

Protein Synthesis by Free and Bound Paramecium Ribosomes in Vivo and in Vitro

SYNOPSIS. Cytoplasmic extracts of Paramecium aurelia were fractionated by density gradient centrifugation. The gradient fractions were characterized by chemical analysis and electron microscopy. Membrane-bound ribosomes were separated from free polyribosomes and the ability of each of these forms to incorporate C¹⁴-leucine into protein was tested. Incorporation was measured in both in vivo and in vitro systems, and similar results were obtained in both types of experiment except that there was little release of soluble labelled protein in the in vitro system. Paramecium appears to synthesize most of its protein on free polyribosomes but membrane-bound ribosomes constitute an important protein synthetic fraction, perhaps accounting for as much as 30% of the total synthesis. When isolated in the in vitro system, increasing concentration of the ribosome fraction gave increased incorporation, but increasing concentration of the membrane fraction gave decreased incorporation after a critical value. This inhibitory effect can be removed by adding excess cytoplasmic-supernatant to the system. The nature of the association of ribosomes with membranes is discussed.     

Effect of neuraminidase treatment on the lipid fluidity of the intestinal brush-border membranes

The effect of neuraminidase treatment on the lipid fluidity of the porcine intestinal brush-border membranes was studied using two fluorescence dyes, pyrene and 1,6-diphenyl-1,3,5-hexatriene. By treatment of the membranes with neuraminidase, the fluorescence parameters of pyrene-labeled membranes changed; i.e., a shift of thermal transition temperature, an increase in the fluorescence quenching rate for Tl+ and a decrease in the fluorescence lifetime. These results suggest that the environmental properties around the dye molecules in the membranes change sensitively upon neuraminidase treatment. Perturbation of the lipid domain in the membranes associated with neuraminidase treatment is also demonstrated by a stimulated solubilization of diphenylhexatriene molecules in the membrane lipids, an increased quenching efficiency with Tl+ and a decreased rotational correlation time of diphenylhexatriene-labeled membranes. Based on these results, we conclude that the lipid organization of the membranes is susceptible to neuraminidase treatment and that the membrane lipid fluidity increases by desialylation by the enzyme treatment.     

Study of the regulation of plastid development in Euglena gracilis. II. Functional localisation and synthesis of ribosomal chloroplast particles (author's transl)]

Chloroplast ribosomes in greening cells of Euglena gracilis are found either in the stroma or bound to thylakoid membranes. The membrane-bound chloroplast ribosomes are of two main types: those which can be released by 0.5 M KCl or by puromycin and 0.5 M KCl, and those which are released by detergent (deoxycholate or Triton X-100) and KCl. The ribosomes which are released by puromycin are presumably bound to chloroplast membrane by nascent peptide chains. Ribosomes released by puromycin are found only during the course of plastidial differentiation at the time of active thylacoid membrane synthesis. Following greening, those ribosomes remain bound to the membranes but can be removed by KCl alone. An analysis of RNA labelling showed that 30-S but not 53-S subunits of membrane-bound ribosomes are of uniform specific activity. This suggests that 30-S subunit exchange in a common pool while 53 S subunits remain membrane bound and do not exchange in a common pool. Membrane-bound chloroplast ribosomes which are released either by puromycin or by detergent are originally derived from loosely bound particles, released by 0.5 M KCl.