Ontogeny of microbodies (glyoxysomes) in cotyledons of dark-grown watermelon (Citrullus vulgaris Schrad.) seedlings

The development of glyoxysomal marker enzyme activities and concomitant ultrastructural evidence for the ontogeny of glyoxysomes has been studied in cotyledons of dark-grown watermelon seedlings (Citrullus vulgaris Schrad., var. Florida Giant). Catalase (CAT, EC 1.11.1.6) was stained in glyoxysomal structures with the 3,3-diaminobenzidine procedure. Serial sections and high-voltage electron microscopy were used to analyze the three-dimensional structure of the glyoxysomal population. With early germination CAT was localized in three distinct cell structures: spherical microbodies already present in freshly imbibed cotyledons; in appendices on lipid bodies; and in small membrane vesicles between the lipid bodies. Due to their ribosome-binding capacity, both appendices and small vesicles were identified as derivatives of the endoplasmic reticulum (ER). In the following period, glyoxysome formation and lipid body degradation were found to be inseparable processes. The small CAT-containing vesicles attach to a lipid body on a restricted area. Both lipid body appendices and attached cisternae enlarge around and between tightly packed lipid bodies and eventually become pleomorphic glyoxysomes with lipid bodies entrapped into cavities. The close contact between lipid body and glyoxysomes is maintained until the lipid body is digested and the glyoxysomal cavity becomes filled with cytoplasm. During the entire period of increase in glyoxysomal enzyme activities, no evidence was obtained for destruction of glyoxysomes, but small CAT-containing vesicles were observed from day 2 through day 6 after imbibition, indicating a continuous de novo formation of glyoxysomes. This study does not substantiate the hypothesis that glyoxysomes bud directly from the ER. Rather, ER-derivatives, e.g., lipid body appendices or cisternae attached to lipid bodies are interpreted as being glyoxysomal precursors that grow in close contact with lipid bodies both in volume and surface membrane area.Abbreviations CAT catalase - DAB 3,3 diaminobenzidine tetrahydrochloride - ER endoplasmic reticulum - GOX glycolate oxidase - HPR hydroxypyruvate reductase - HVEM high-voltage electron microscopy - ICL isocitrate lyase - MS malate synthase - RER rough endoplasmic reticulum In the figures bars represent 0.1 m (if not stated otherwise)     

Evidence that glyoxysomal malate synthase is segregated by the endoplasmic reticulum

At the onset of castor bean (Ricinus communis) germination, 76% of the cellular malate synthase activity of the endosperm tissue was located in the microsomal fraction, with the remainder in the glyoxysomal fraction. During later developmental stages, when rapid malate synthase synthesis was occurring, an increasing proportion of the enzyme was recovered in glyoxysomes. The kinetics of [³⁵S]methionine incorporation into microsomal and glyoxysomal malate synthase in 2-day-old endosperm tissue was followed by employing antiserum raised against glyoxysomal malate synthase to precipitate specifically the enzyme from KCl extracts of these organelle fractions. This experiment showed that microsomal malate synthase was labeled before the glyoxysomal enzyme. When such kinetic experiments were interrupted by the addition of an excess of unlabeled methionine, ³⁵S-labeled malate synthase was rapidly lost from the microsomal fraction and was quantitatively recovered in the glyoxysomal fraction.

Free cytoplasmic ribosomes were separated from bound ribosomes (rough microsomes) using endosperm tissue labeled with [³⁵S]methionine or ¹⁴C-amino-acids. Nascent polypeptide chains were released from polysome fractions using a puromycin-high salt treatment, and radioactive malate synthase was shown to be exclusively associated with bound polysomes.

Together these data establish that malate synthase is synthesized on bound ribosomes and vectorially discharged into the endoplasmic reticulum cisternae prior to its ultimate sequestration in glyoxysomes.

     

Purification and comparative properties of microsomal and glyoxysomal malate synthase from castor bean endosperm

Sucrose density gradient centrifugation was employed to separate microsomes, mitochondria, and glyoxysomes from homogenates prepared from castor bean (Ricinus communis) endosperm. In the case of tissue removed from young seedlings, a significant proportion of the characteristic glyoxysomal enzyme malate synthase was recovered in the microsomal fraction. Malate synthase was purified from both isolated microsomes and glyoxysomes by a procedure involving osmotic shock, KCI solubilization, and sucrose density gradient centrifugation. All physical and catalytic properties examined were identical for the enzyme isolated from both organelle fractions. These properties include a molecular weight of 575,000, with a single subunit type of molecular weight 64,000, a pH optimum of 8, apparent K_m for acetyl-CoA of 10 μm and glyoxylate of 2 mm. Microsomal and glyoxysomal malate synthases showed identical responses to various inhibitors. Adenine nucleotides were competitive inhibitors with respect to acetyl-CoA, and oxalate (K_i 110 μm) and glycolate (K_i 150 μm) were competitive inhibitors with respect to glyoxylate. Antiserum raised in rabbits against purified glyoxysomal malate synthase was used to confirm serological identity between the microsomal and glyoxysomal enzymes, and was capable of specifically precipitating ³⁵S-labeled malate synthase from KCI extracts of both microsomes and glyoxysomes isolated from [³⁵S]methionine-labeled endosperm tissue.     

Serological and developmental relationships between endoplasmic reticulum and glyoxysomal proteins of castor bean endosperm

Glyoxysomes isolated from the endosperm of castor bean (Ricinus communis L.) by sucrose density gradient centrifugation were fractionated into their matrix protein and membrane components. Antisera were raised in rabbits against both the matrix proteins and sodium dodecyl sulphate (SDS)-solubilized membrane proteins. SDS-polyacrylamide gel electrophoresis (PAGE) analysis established that such antisera precipitate all major polypeptide components present in their respective glyoxysomal mixedantigen preparations. Furthermore, when soluble constituents recovered from the microsomal vesicles or solubilized microsomal membranes were challenged with the appropriate glyoxysomal antiserum, serological determinants were again found to be present. Intact endosperm tissue was incubated with [³⁵S]methionine and the kinetics of ³⁵S-incorporation into protein recovered in immunoprecipitates when the glyoxysomal matrix fraction or the soluble fraction released from the microsomes were incubated with anti-glyoxysomal matrix serum were followed. [³⁵S]antigens rapidly appeared in the microsomal fraction whereas a lag period preceded their appearance in glyoxysomes. Interupting such kinetic experiments by the addition of an excess of unlabelled methionine resulted in a rapid decrease in the microsomal content of [³⁵S]antigens and a concomitant increase in glyoxysomal content.Abbreviations SDS sodium dodecyl sulphate - PAGE polyacrylamide gel electrophoresis - ER endoplasmic reticulum     

Different routes for integral protein insertion into Ricinus communis protein-body and glyoxysome membranes

Total polyadenylated RNA from ripening or germinating Ricinus communis L. endosperm was translated in rabbit reticulocyte lysate in the absence or presence of canine pancreatic microsomes. The products were immunoprecipitated using antibodies raised againts Triton X-114-extracted integral membrane proteins of protein bodies or glyoxysomes. While the proteins of proteinbody membranes were found to insert co-translationally into added microsomes, this was not observed in the case of glyoxysomal proteins. This observation was confirmed using antibodies raised against a purified glyoxysome membrane protein, alkaline lipase. These results indicate that different routes exist for the insertion of membrane proteins into the two organelles. In both cases membrane-protein insertion does not appear to be accompanied by proteolytic processing.Abbreviations anti-PB antiserum to integral protein-body membrane proteins - anti-G antiserum to integral glyoxysomal membrane proteins - anti-L antiserum to alkaline lipase - ER endoplasmic reticulum - M_r relative molecular mass - mRNA poly(A)-rich messenger RNA - PAGE polyacrylamide gel electrophoresis - poly(A) polyadenylic acid - SDS sodium dodecyl sulphate     

Biogenesis of endoplasmic reticulum membrane in rat liver cells. II. Discharge of the nascent peptides of NADPH-cytochrome c reductase and cytochrome b5 on the cytoplasmic side of the endoplasmic reticulum membrane.

The direction of discharge of the nascent peptides of NADPH-cytochrome c reductase and cytochrome b5 from bound polyribosomes of rough microsomes was investigated in order to elucidate the mechanism of separation of these membrane proteins from secretory proteins, which are also synthesized by the same class of ribosomes of rough endoplasmic reticulum. The nascent peptides of NADPH-cytochrome c reductase and cytochrome b5 in intact rough microsomes were accessible to externally added 125I-Fab's against these proteins, and were susceptible to trypsin digestion, whereas the nascent peptides of serum albumin were not. The nascent peptides of these two microsomal proteins were released into the cytoplasm by puromycin treatment of intact rough microsomes, while the nascent peptides of serum albumin were retained in the microsomal lumen. These observations suggest that the nascent peptides of microsomal proteins, which are present on the cytoplasmic surface of the endoplasmic reticulum membrane, are exposed on the surface of microsomal vesicles, while those of secretory proteins are enclosed inside the vesicles. Therefore, the topographical separation of microsomal membrane proteins from secretory proteins is accomplished at the step of their synthesis by the bound polyribosomes of rough endoplasmic reticulum.     

Recovery of ribophorins and ribosomes in "inverted rough" vesicles derived from rat liver rough microsomes

Treatment of rat liver rough microsomes (3.5 mg of protein/ml) with sublytical concentrations (0.08%) of the neutral detergent Triton X-100 caused a lateral displacement of bound ribosomes and the formation of ribosomal aggregates on the microsomal surface. At slightly higher detergent concentrations (0.12-0.16%) membrane areas bearing ribosomal aggregates invaginated into the microsomal lumen and separated from the rest of the membrane. Two distinct classes of vesicles could be isolated by density gradient centrifugation from microsomes treated with 0.16% Triton X-100: one with ribosomes bound to the inner membrane surfaces ("inverted rough" vesicles) and another with no ribosomes attached to the membranes. Analysis of the fractions showed that approximately 30% of the phospholipids and 20-30% of the total membrane protein were released from the membranes by this treatment. Labeling with avidin-ferritin conjugates demonstrated that concanavalin A binding sites, which in native rough microsomes are found in the luminal face of the membranes, were present on the outer surface of the inverted rough vesicles. Freeze-fracture electron microscopy showed that both fracture faces had similar concentrations of intramembrane particles. SDS PAGE analysis of the two vesicle subfractions demonstrated that, of all the integral microsomal membrane proteins, only ribophorins I and II were found exclusively in the inverted rough vesicles bearing ribosomes. These observations are consistent with the proposal that ribophorins are associated with the ribosomal binding sites characteristic of rough microsomal membranes.     

Intraorganellar distribution of superoxide dismutase in plant peroxisomes (glyoxysomes and leaf peroxisomes)

The intraorganellar distribution of superoxide dismutase (SOD) (EC 1.15.1.1) in two types of plant peroxisomes (glyoxysomes and leaf peroxisomes) was studied by determinations of SOD latency in intact organelles and by solubilization assays with 0.2 molar KCl. Glyoxysomes were purified from watermelon (Citrullus vulgaris Schrad.) cotyledons, and their integrity, calculated on the basis of glyoxysomal marker enzymes, was about 60%. Under the same conditions, the latency of SOD activity determined in glyoxysomes was 40%. The difference between glyoxysomal intactness and SOD latency was very close to the percentage of isozyme Mn-SOD previously determined in glyoxysomes (LM Sandalio, LA Del Río 1987 J Plant Physiol 127: 395-409). In matrix and membrane fractions of glyoxysomes, SOD exhibited a solubilization pattern very similar to catalase, a typical soluble enzyme of glyoxysomes. The analysis of the distribution of individual SOD isozymes in glyoxysomal fractions treated with KCl showed that Cu,Zn-SOD II, the major SOD isozyme in glyoxysomes, was present in the soluble fraction of these organelles, whereas Mn-SOD was bound to the glyoxysomal membrane. These data in conjunction with those of latency of SOD activity in intact glyoxysomes suggest that Mn-SOD is bound to the external side of the membrane of glyoxysomes. On the other hand, in intact leaf peroxisomes where only a Mn-containing SOD is present (LM Sandalio, JM Palma, LA Del Río 1987 Plant Sci 51: 1-8), this isozyme was found in the peroxisomal matrix. The physiological meaning of SOD localization in matrix and membrane fractions of glyoxysomes and the possibility of new roles for plant peroxisomes in cellular metabolism related to activated oxygen species is discussed.     

Direct interaction between glyoxysomes and lipid bodies in cotyledons of theArabidopsis thaliana ped1 mutant

Summary During germination and subsequent growth of fatty seeds, higher plants obtain energy from the glyconeogenic pathway in which fatty acids are converted to succinate in glyoxysomes, which contain enzymes for fatty acid -oxidation and the glyoxylate cycle. TheArabidopsis thaliana ped1 gene encodes a 3-ketoacyl-CoA thiolase (EC 2.3.1.16) involved in fatty acid -oxidation. Theped1 mutant shows normal germination and seedling growth under white light. However, etiolated cotyledons of theped1 mutant grow poorly in the dark and have small cotyledons. To elucidate the mechanisms of lipid degradation during germination in theped1 mutant, we examined the morphology of theped1 mutant. The glyoxysomes in etiolated cotyledons of theped1 mutant appeared abnormal, having tubular structures that contained many vesicles. Electron microscopic analysis revealed that the tubular structures in glyoxysomes are derived from invagination of the glyoxysomal membrane. By immunoelectron microscopic analysis, acyl-CoA synthetase (EC 6.2.1.3), which was located on the membrane of glyoxysomes in wild-type plants, was located on the membranes of the tubular structures in the glyoxysomes in theped1 mutant. These invagination sites were always in contact with lipid bodies. The tubular structure had many vesicles containing substances with the same electron density as those in the lipid bodies. From these results, we propose a model in which there is a direct mechanism of transporting lipids from the lipid bodies to glyoxysomes during fatty acid -oxidation.     

Determination of the membrane topology of the phenobarbital-inducible rat liver cytochrome P-450 isoenzyme PB-4 using site-specific antibodies

Fifteen peptides, ranging in length from 6 to 31 amino acids and corresponding in sequence to portions of the major phenobarbital-inducible form of rat liver cytochrome P-450 (P-450 PB-4), were previously synthesized chemically and used to prepare site-specific rabbit antibodies (Frey, A. B., D.J. Waxman, and G. Kreibich, 1985, J. Biol. Chem., 260:15253-15265). The antipeptide antibodies were affinity purified using Sepharose resins derivatized with the respective peptides and 14 preparations were obtained that in an ELISA assay showed affinities to immobilized P-450 judged to be adequate for binding studies on intact rat liver microsomes. The binding of these antibodies to rough microsomes from the livers of phenobarbital treated rats was assessed using 125I-labeled IgG and by immunoelectron microscopy employing protein A-gold as a marker. It was found that many of the antibodies bound to the cytoplasmic surface of the membrane but none bound to the luminal face of ruptured or inverted microsomal vesicles or to contaminating membranes of other organelles present in the preparations. These observations eliminate previously proposed models for the transmembrane disposition of P-450 that postulate the existence of multiple transmembrane domains and the exposure of several polar segments of the polypeptide on the luminal side of the membrane. The fact that an antibody raised to the first 31 residues of P-450 bound well to the purified P-450 but very poorly to rough microsomes, whereas an antibody to a peptide comprising residues 24-38 showed relatively strong binding to intact microsomes, is consistent with the proposal that the amino terminal segment of P-450 extending approximately to residue 20 is embedded in the phospholipid bilayer and the immediately following segment is exposed on the cytoplasmic surface of the membrane. All these results favor a model in which the cytochrome P-450 molecule is largely exposed on the cytoplasmic surface of the endoplasmic reticulum membrane to which it is anchored by its short amino terminal hydrophobic segment.     

Novel glyoxysomal protein kinase, GPK1, identified by proteomic analysis of glyoxysomes in etiolated cotyledons of Arabidopsis thaliana

Glyoxysomes are present in etiolated cotyledons and contain enzymes for gluconeogenesis, which constitutes the major function of glyoxysomes. However, 281 genes seemingly related to peroxisomal functions occur in the Arabidopsis genome, implying that many unidentified proteins are present in glyoxysomes. To better understand the functions of glyoxysomes, we performed glyoxysomal proteomic analysis of etiolated Arabidopsis cotyledons. Nineteen proteins were identified as glyoxysomal proteins, including 13 novel proteins, one of which is glyoxysomal protein kinase 1 (GPK1). We cloned GPK1 cDNA by RT-PCR and characterized GPK1. The amino acid sequence deduced from GPK1 cDNA has a hydrophobic region, a putative protein kinase domain, and a possible PTS1 motif. Immunoblot analysis using fractions collected on a Percoll density gradient confirmed that GPK1 is localized in glyoxysomes. Analysis of suborganellar localization and protease sensitivity showed that GPK1 is localized on glyoxysomal membranes as a peripheral membrane protein and that the putative kinase domain is located inside the glyoxysomes. Glyoxysomal proteins are phosphorylated well in the presence of various metal ions and [g-32P]ATP, and one of them is identified as thiolase by immunoprecipitation. Immuno-inhibition of phosphorylation in glyoxysomes suggested that GPK1 phosphorylates a 40-kDa protein. These results show that protein phosphorylation systems are operating in glyoxysomes.     

The latency of rat liver microsomal protein disulphide-isomerase.

Protein disulphide-isomerase (PDI) activity was not detectable in freshly prepared rat liver microsomes (microsomal fraction), but became detectable after treatments that damage membrane integrity, e.g. sonication, detergent treatment or freezing and thawing. Maximum activity was detectable after sonication. Identical latency was observed in microsomes prepared by gel filtration and in those prepared by high-speed centrifugation. PDI activity was latent in all particulate subcellular fractions, but not latent in the high-speed supernatant. When all fractions were sonicated to expose total PDI activity, PDI was found at highest specific activity in the microsomal fraction and co-distributed with marker enzymes of the endoplasmic reticulum. Washing of microsomes under various conditions that removed peripheral proteins and, in some cases, bound ribosomes did not remove significant quantities of PDI, nor did it affect the latency of PDI activity. Treatment of microsomes with proteinases, under conditions where the permeability barrier of the microsomal vesicles was maintained intact, did not inactivate PDI significantly or affect its latency. PDI was very readily solubilized from microsomal vesicles by low concentrations of detergents, which removed only a fraction of the total microsomal protein. In all these respects, PDI resembled nucleoside diphosphatase, a marker peripheral protein of the luminal surface of the endoplasmic reticulum, and differed from NADPH: cytochrome c reductase, a marker integral protein exposed at the cytoplasmic surface of the membrane. The data are compatible with a model in which PDI is loosely associated with the luminal surface of the endoplasmic reticulum, a location consistent with the proposed physiological role of the enzyme as catalyst of formation of native disulphide bonds in nascent and newly synthesized secretory proteins.     

Fatty acid β-oxidation and glyoxylate cycle enzyme activities of induced glyoxysomes from anise suspension cultures

Homogenates of dedifferentiated anise (Pimpinella anisum L.) suspension cultures grown in B-5 medium with sucrose as source of carbon show all but 3 glyoxysomal enzyme activities: NAD-dependent oxidation of palmitoyl-CoA, isocitrate lyase, and malate synthase are lacking. Substitution of 20 mmol/l acetate for sucrose leads to the appearance of these enzyme activities. Only then glyoxysomes with a buoyant density of 1.23 kg/l in sucrose gradients are formed showing the enzyme activities for both ß-oxidation of fatty acids and glyoxylate cycle. Quantitatively and qualitatively they resemble glyoxysomes isolated from endosperm of 4 d old anise seedlings. Therefore, the suspension cultures constitute a valuable system for the study of both mechanisms and regulation of glyoxysome formation in anise.     

Relationship between Cottonseed Malate Synthase Aggregation Behavior and Suborganellar Location in Glyoxysomes and Endoplasmic Reticulum

Malate synthase (EC 4.1.3.2) (MS), an enzyme unique to the glyoxylate cycle, was studied in cotyledons of dark-grown cotton (Gossypium hirsutum, L.) seedlings. MS has generally been regarded as a peripheral membrane protein in glyoxysomes and believed by some to be synthesized on rough ER. Immunocyto-chemical localization of MS in both in situ and isolated cottonseed glyoxysomes, however, showed that MS was located throughout the matrix of glyoxysomes, not specifically associated with their membranes. Biochemical data also supported matrix localization. Isolated glyoxysomes were diluted in variously-buffered salt solutions (200 millimolar KCl or 100 millimolar K-phosphate) or detergents (0.1% Triton X-100, 10 millimolar deoxycholate, or 1.0% Triton X-114) and centrifuged to pellet membranes. Greater than 70% of the MS was recovered in supernatants after treatment with salt solutions, whereas generally less than 30% was released following detergent treatments. MS in pellets derived from glyoxysomes burst in low ionic strength buffer solutions was aggregated (observed on rate-zonal gradients). MS released following salt treatments was the 20S nonaggregated form indicating that salt solutions either disaggregated (or prevented aggregation of) glyoxysomal MS rather than releasing it from membranes. We confirmed reports by others that MS comigrated with ER (NADH: cytochrome c reductase) in sucrose (20-40% w/w) gradients buffered with 100 millimolar Tricine (pH 7.5) after 3 hours centrifugation. However, cottonseed MS did not comigrate with ER in gradients buffered with 10 millimolar Hepes (pH 7.0) or 20 millimolar K-phosphate (pH 7.2) after 3 hours centrifugation, or after 22 hours centrifugation in Tricine or Hepes. Collectively, our data with cotton seeds indicate that MS is not a peripheral membrane protein, and that the aggregation behavior of MS (in various buffers) very likely has led to misinterpretations of its putative associations with ER and glyoxysomal membranes.     

Electron microscopic studies of coated membranes in two types of gill epithelial cells of lamprey

Summary Coated membranes in two types of gill epithelial cell of adult lamprey, Lampetra japonica, were studied by electron microscopy. The type 3 gill epithelial cells possess well-developed microvilli or microfolds, apical vesicles and abundant mitochondria. The cytoplasmic surface of the microvillous plasma membrane is covered by a coat of regularly spaced particles with a center-to-center distance of about 15 nm. Each particle consists of a bulbous free end, about 10 nm in diameter, and a connecting piece, about 5 nm long. Apical vesicles are covered by a surface coat which consists of fine filamentous material but lack any special coating on their cytoplasmic surface.The type 4 cells (chloride cells) are characterized by apical vesicles, abundant mitochondria and cytoplasmic tubules. These tubules possess a coat on their luminal surface which consists of spirally wound parallel rows of electron-dense materials. The rows are about 16 nm apart and wound at a pitch of about 45°. The cytoplasmic surface of these tubules does not display a special coat. These coated membranes are assumed to be the sites of active ion transport across the plasma membrane. In particular, particles in type 3 cells and linear coat materials in chloride cells may be either loci of transport enzymes or energy generating systems. Apical vesicles lack any coating on their cytoplasmic surface but a fine filamentous coat is present on their luminal surface. They contain intraluminal vesicles and are continuous with apical ends of cytoplasmic tubules.     

Development of Microbody Membrane Proteins during the Transformation of Glyoxysomes to Leaf Peroxisomes in Pumpkin Cotyledons

The microbody transition observed in the cotyledons of somefatty seedlings involves the conversion of glyoxysomes to leafperoxisomes. To clarify the molecular mechanisms underlyingthe microbody transition, we established a method for the preparationof highly purified microbodies. SDS-PAGE and immunoblot analysisof isolated microbodies from pumpkin cotyledons at various stagesshowed that glyoxysomal enzymes are replaced by leaf-peroxisomalenzymes during the microbody transition. Two proteins in glyoxysomalmembranes, with molecular masses of 31 kDa and 28 kDa, werenot solubilized from the membranes with 0.2 M KCl, an indicationthat these proteins are bound tightly with glyoxysomal membranes.Their polyclonal antibodies were raised against the respectivepurified protein. Immunoblot analysis of subcellular fractionsand immunogold analysis confirmed that these proteins were specificallylocalized on glyoxysomal membranes. Analysis of these membraneproteins during development revealed that the amounts of thesemembrane proteins decreased during the microbody transitionand that the large one was retained in leaf peroxisomes, whereasthe small one could not be found in leaf peroxisomes after completionof the microbody transition. The results clearly showed thatmembrane proteins in glyoxysomes change dramatically duringthe microbody transition, as do the enzymes in the matrix. ¹Present address: School of Agriculture, Nagoya University Chikusa,Nagoya, 464-01 Japan.     

Development of Endoplasmic Reticulum and Glyoxysomal Membrane Redox Activities during Castor Bean Germination

Redox activities, NADH:ferricyanide reductase, NAD(P)H:cytochrome reductases, and NADH:ascorbate free-radical reductase, are present in endoplasmic reticulum (ER) and glyoxysomal membranes from the endosperm of germinating castor bean (Ricinus comminus L. var Hale). The development of these functions was followed in glyoxysomes and ER isolated on sucrose gradients from castor bean endosperm daily from 0 through 6 days of germination. On a per seed basis, glyoxysomal and ER protein, glyoxysomal and ER membrane redox enzyme activities, and glyoxylate cycle activities peaked at day 4 as did the ER membrane content of cytochrome P-450. NADH:ferricyanide reductase was present in glyoxysomes and ER isolated from dry seed. This activity increased only about twofold in glyoxysomes and threefold in ER during germination relative to the amount of protein in the respective fractions. The other reductases, NADH:cytochrome reductase and NADH:ascorbate free-radical reductase, increased about 10-fold in the ER relative to protein up to 4 to 5 days, then declined. NADPH:cytochrome reductase reached maximum activity relative to protein at day 2 in both organelles. The increases in redox activities during germination indicate that the membranes of the ER and glyoxysome are being enriched with redox proteins during their development. The development of redox functions in glyoxysomes was found to be coordinated with development of the glyoxylate cycle.     

Spatial orientation of glycoproteins in membranes of rat liver rough microsomes. I. Localization of lectin-binding sites in microsomal membranes

Carbohydrate-containing structures in rat liver rough microsomes (RM) were localized and characterized using iodinated lectins of defined specificity. Binding of [125I]Con A increased six- to sevenfold in the presence of low DOC (0.04--0.05%) which opens the vesicles and allows the penetration of the lectins. On the other hand, binding of [125I]WGA and [125I]RCA increased only slightly when the microsomal vesicles were opened by DOC. Sites available in the intact microsomal fraction had an affinity for [125I]Con A 14 times higher than sites for lectin binding which were exposed by the detergent treatment. Lectin-binding sites in RM were also localized electron microscopically with lectins covalently bound to biotin, which, in turn, were visualized after their reaction with ferritin-avidin (F-Av) markers. Using this method, it was demonstrated that in untreated RM samples, binding sites for lectins are not present on the cytoplasmic face of the microsomal vesicles, even after removal of ribosomes by treatment with high salt buffer and puromycin, but are located on smooth membranes which contaminate the rough microsomal fraction. Combining this technique with procedures which render the interior of the microsomal vesicles accessible to lectins and remove luminal proteins, it was found that RM membranes contain binding sites for Con A and for Lens culinaris agglutinin (LCA) located exclusively on the cisternal face of the membrane. No sites for WGA, RCA, soybean (SBA) and Lotus tetragonobulus (LTA) agglutinins were detected on either the cytoplasmic or the luminal faces of the rough microsomes. These observations demonstrate that: (a) sugar moieties of microsomal glycoproteins are exposed only on the luminal surface of the membranes and (b) microsomal membrane glycoproteins have incomplete carbohydrate chains without the characteristic terminal trisaccharides N-acetylglucosamine comes from galactose comes from sialic acid or fucose present in most glycoproteins secreted by the liver. The orientation and composition of the carbohydrate chains in microsomal glycoproteins indicate that the passage of these glycoproteins through the Golgi apparatus, followed by their return to the endoplasmic reticulum, is not required for their biogenesis and insertion into the endoplasmic reticulum (ER) membrane.     

Biosynthesis and localization of rat liver microsomal carboxyesterase E1

One of the microsomal carboxyesterases, carboxyesterase E1, was purified from rat liver to homogeneity. Carboxyesterase E1 is a glycoprotein of high mannose type, and is composed of three identical subunits of 59 kDa each. It is very similar to "esterase pI 6.0" described by Menthein et al. (Arch. Biochem. Biophys. 200, 547-559 (1980)) in molecular weight, amino acid composition, and enzymic activities. Carboxyesterase E1 was found to be evenly distributed between rough and smooth microsomes. The content of the enzyme in microsomes was about 1.5% of total microsomal protein. It was exclusively located on the luminal side of microsomes, and was not detected immunologically in Golgi fractions or serum. In vitro translation of rat liver RNA by reticulocyte lysate showed that carboxyesterase E1 was synthesized preferentially on the bound ribosomes, as a precursor peptide larger than the peptide of the mature enzyme. Carboxyesterase E1 was solubilized from microsomes by treatment with low concentrations of detergents. However, it was not released from microsomes by treatment with a synthetic peptide which made the microsomal membrane permeable to soluble protein molecules. Carboxyesterase E1 is not a soluble luminal protein, and seems to be bound to the luminal surface of the membrane.     

Biogenesis of endoplasmic reticulum membrane in rat liver cells. III. Biosynthesis of NADPH-cytochrome c reductase and cytochrome b5 by loosely-bound ribosomes.

Membrane-bound ribosomes were separated into two distinct classes (loosely-bound and tightly-bound ribosomes) by treatment with 0.6 M KCl, 1 mM puromycin, 0.05% DOC, or 10 mM EDTA. It was also confirmed that any one of these reagents except for EDTA dissociated the same class of ribosomes from the membrane. A population of lighter microsomal vesicles was formed from rough microsomes upon the dissociation of loosely-bound ribosomes by treatment with these chemicals. Rough microsomes were subfractionated into lighter and heavier fractions, L-rMs and H-rMs, by centrifugation using a discontinuous gradient of sucrose consisting of 1.3 M, 1.5 M, and 2.1 M solutions. It was found that L-rMs was rich in loosely-bound ribosomes, whereas H-rMs contained a high proportion of tightly-bound ribosomes. It is likely that loosely-bound and tightly-bound ribosomes are heterogeneously distributed among rough microsomal vesicles. Loosely-bound ribosomes and tightly-bound ribosomes synthesize different kinds of proteins. Two microsomal membrane proteins, NADPH-cytochrome c reductase and cytochrome b5, were exclusively synthesized by loosely-bound ribosomes, whereas serum albumin, which is a major component of the secretory proteins of hepatocytes, was synthesized only by tightly-bound ribosomes. Since the nascent peptides of NADPH-cytochrome c reductase and cytochrome b5 are released from bound ribosomes to the cytoplasmic surface of endoplasmic reticulum, while those of secretory proteins are discharged into the lumen across the membrane, the strength of the association between ribosomes and microsomal membrane seems to be correlated with the direction of release of nascent peptides.