Identification of protein transport complexes in the chloroplastic envelope membranes via chemical cross-linking.

Transport of cytoplasmically synthesized proteins into chloroplasts uses an import machinery present in the envelope membranes. To identify the components of this machinery and to begin to examine how these components interact during transport, chemical cross-linking was performed on intact chloroplasts containing precursor proteins trapped at a particular stage of transport by ATP limitation. Large cross-linked complexes were observed using three different reversible homobifunctional cross-linkers. Three outer envelope membrane proteins (OEP86, OEP75, and OEP34) and one inner envelope membrane protein (IEP110), previously reported to be involved in protein import, were identified as components of these complexes. In addition to these membrane proteins, a stromal member of the hsp100 family, ClpC, was also present in the complexes. We propose that ClpC functions as a molecular chaperone, cooperating with other components to accomplish the transport of precursor proteins into chloroplasts. We also propose that each envelope membrane contains distinct translocation complexes and that a portion of these interact to form contact sites even in the absence of precursor proteins.

Immunocytochemical localization of wheat germ agglutinin in wheat.

Immunocytological techniques were developed to localize the plant lectin, wheat germ agglutinin (WGA), in the tissues and cells of wheat plants. In a previous study we demonstrated with a radioimmunoassay that the lectin is present in wheat embryos and adult plants both in the roots and at the base of the stem. We have now found, using rhodamine, peroxidase, and ferritin-labeled secondary antibodies, that WGA is located in cells and tissues that establish direct contact with the soil during germination and growth of the plant In the embryo, WGA is found in the surface layer of the radicle, the first adventitious roots, the coleoptile, and the scutellum. Although found throughout the coleorhiza and epiblast, it is at its highest levels within the cells at the surface of these organs. In adult plants, WGA is located only in the caps and tips of adventitious roots. Reaction product for WGA was not visualized in embryonic or adult leaves or in other tissues of adult plants. At the subcellular level, WGA is located at the periphery of protein bodies, within electron-translucent regions of the cytoplasm, and at the cell wall-protoplast interface. Since WGA is found at potential infection sites and is known to have fungicidal properties, it may function in the defense against fungal pathogens.

Stop-transfer regions do not halt translocation of proteins into chloroplasts.

Protein targeting in eukaryotic cells is determined by several topogenic signals. Among these are stop-transfer regions, which halt translocation of proteins across the endoplasmic reticulum membrane. Two different stop-transfer regions were incorporated into precursors for a chloroplast protein, the small subunit of ribulose-1,5-bisphosphate carboxylase/oxygenase. Both chimeric proteins were imported into chloroplasts and did not accumulate in the envelope membranes. Thus, the stop-transfer signals did not function during chloroplast protein import. These observations support the hypothesis that the mechanism for translocation of proteins across the chloroplast envelope is significantly different from that for translocation across the endoplasmic reticulum membrane.

Localization of wheat germ agglutinin--like lectins in various species of the gramineae.

Antigenically similar chitin-binding lectins are present in the embryos of wheat, barley, and rye, members of the Triticeae tribe of the grass family (Gramineae). However, the lectins display different localization patterns in these embryos. Lectin is absent from the coleoptile of barley but is present in the outer surface cells of this organ in wheat and in both inner and outer surface cells of rye coleoptiles. All three cereals contain lectin at the periphery of embryonic roots. Similar lectins were not detected in oats and pearl millet, members of other tribes of the Gramineae. Rice, a species only distantty related to wheat, contains a lectin that is antigenically similar to the other cereal lectins and located at the periphery of embryonic roots and throughut the coleoptile.

Xyloglucan fucosyltransferase, an enzyme involved in plant cell wall biosynthesis.

Cell walls are crucial for development, signal transduction, and disease resistance in plants. Cell walls are made of cellulose, hemicelluloses, and pectins. Xyloglucan (XG), the principal load-bearing hemicellulose of dicotyledonous plants, has a terminal fucosyl residue. A 60-kilodalton fucosyltransferase (FTase) that adds this residue was purified from pea epicotyls. Peptide sequence information from the pea FTase allowed the cloning of a homologous gene, AtFT1, from Arabidopsis. Antibodies raised against recombinant AtFTase immunoprecipitate FTase enzyme activity from solubilized Arabidopsis membrane proteins, and AtFT1 expressed in mammalian COS cells results in the presence of XG FTase activity in these cells.

Plant glycosyltransferases.

Glycosyltransferases are involved in the biosyntheses of cell-wall polysaccharides, the addition of N-linked glycans to glycoproteins, and the attachment of sugar moieties to various small molecules such as hormones and flavonoids. In the past two years, substantial progress has been made in the identification and cloning of genes that encode glycosyltransferases. Moreover, analysis of the recently completed Arabidopsis genome sequence indicates the existence of several hundred additional genes encoding putative glycosyltransferases.

Protein import into chloroplasts.

Three proteins from the chloroplastic outer envelope membrane and four proteins from the inner envelope membrane have been identified as components of the chloroplastic protein import apparatus. Multiple molecular chaperones and a stromal processing peptidase are also important components of the import machinery. The interactions of these proteins with each other and with the precursors destined for transport into chloroplasts are gradually being described using both biochemical and genetic strategies. Homologs of some transport components have been identified in cyanobacteria suggesting that at least some of import machinery was inherited from the cyanobacterial ancestors that gave rise to chloroplasts.

Molecular chaperones involved in chloroplast protein import.

Transport of cytoplasmically synthesized precursor proteins into chloroplasts, like the protein transport systems of mitochondria and the endoplasmic reticulum, appears to require the action of molecular chaperones. These molecules are likely to be the sites of the ATP hydrolysis required for precursor proteins to bind to and be translocated across the two membranes of the chloroplast envelope. Over the past decade, several different chaperones have been identified, based mainly on their association with precursor proteins and/or components of the chloroplast import complex, as putative factors mediating chloroplast protein import. These factors include cytoplasmic, chloroplast envelope-associated and stromal members of the Hsp70 family of chaperones, as well as stromal Hsp100 and Hsp60 chaperones and a cytoplasmic 14-3-3 protein. While many of the findings regarding the action of chaperones during chloroplast protein import parallel those seen for mitochondrial and endoplasmic reticulum protein transport, the chloroplast import system also has unique aspects, including its hypothesized use of an Hsp100 chaperone to drive translocation into the organelle interior. Many questions concerning the specific functions of chaperones during protein import into chloroplasts still remain that future studies, both biochemical and genetic, will need to address.

Adenine nucleotide translocase-dependent anion transport in pea chloroplasts.

Pea chloroplasts were found to take up actively ATP and ADP and exchange the external nucleotides for internal ones. Using carrier-free [14C]ATP, the rate of nucleotide transport in chloroplasts prepared from 12-14-day-old plants was calculated to be 330 mumol ATP/g chlorophyll/min, and the transport was not affected by light or temperature between 4 and 22 degrees C. Adenine nucleotide uptake was inhibited only slightly by carboxyatractylate, whereas bongkrekic acid was nearly as effective an inhibitor of the translocator in pea chloroplasts as it was in mammalian mitochondria. There was no counter-transport of adenine nucleotides with substrates carried on the phosphate translocator including inorganic phosphate, 3-phosphoglycerate and dihydroxyacetone phosphate. However, internal or external phosphoenolpyruvate, normally considered to be transported on the phosphate carrier in chloroplasts, was able to exchange readily with adenine nucleotides. Furthermore, inorganic pyrophosphate which is not transported by the phosphate carrier initiated efflux of phosphoenolpyruvate as well as ATP from the chloroplast. These findings illustrate some interesting similarities as well as differences between the various plant phosphate and nucleotide transport systems which may relate to their role in photosynthesis.

Lipid-peptide interactions between fragments of the transit peptide of ribulose-1,5-bisphosphate carboxylase/oxygenase and chloroplast membrane lipids.

The interactions of fragments of the transit peptide of ribulose-1,5-bisphosphate carboxylase/oxygenase with lipid monolayers was studied in order to investigate the possible involvement of the membrane lipids in the protein import process. The fragments are surface active and have a differential ability to insert in lipid monolayers. The fragments have a preference for the chloroplast galacto- and sulpholipids and phosphatidylglycerol and interact with envelope membrane lipid extracts. These results suggest that probably transit peptide-lipid interactions are involved in the chloroplast protein import process.

The Involvement of Glycosidases in the Cell Wall Metabolism of Suspension-cultured Acer pseudoplatanus Cells.

Several glycosidases have been isolated from suspensioncultured sycamore (Acer pseudoplatanus) cells. These include an alpha-galactosidase, an alpha-mannosidase, a beta-N-acetyl-glucosaminidase, a beta-glucosidase, and two beta-galactosidases. The pH optimum of each of these enzymes was determined. The pH optima, together with inhibition studies, suggest that each observed glycosidase activity represents a separate enzyme. Three of these enzymes, beta-glucosidase, alpha-galactosidase, and one of the beta-galactosidases, have been shown to be associated with the cell surface. The enzyme activities associated with the cell surface were shown to possess the ability to degrade to a limited extent isolated sycamore cell walls. It was found that the activities of beta-glucosidase and of one of the beta-galactosidases increase as the cells go through a period of growth and decrease as cell growth ceases.

Full-length plastocyanin precursor is translocated across isolated thylakoid membranes.

In higher plants, the chloroplastic protein plastocyanin is synthesized as a transit peptide-containing precursor by cytosolic ribosomes and posttranslationally transported to the thylakoid lumen. En route to the lumen, a plastocyanin precursor is first imported into chloroplasts and then further directed across the thylakoid membrane by a second distinct transport event. A partially processed form of plastocyanin is observed in the stroma during import experiments using intact chloroplasts and has been proposed to be the translocation substrate for the second step (Smeekens, S., Bauerle, C., Hageman, J., Keegstra, K., and Weisbeek, P. (1986) Cell 46, 365-375). To further characterize this second step, we have reconstituted thylakoid transport in a system containing in vitro-synthesized precursor proteins and isolated thylakoid membranes. This system was specific for lumenal proteins since stromal proteins lacking the appropriate targeting information did not accumulate in the thylakoid lumen. Plastocyanin precursor was taken up by isolated thylakoids, proteolytically processed to mature size, and converted to holo form. Translocation was temperature-dependent and was stimulated by millimolar levels of ATP but did not strictly require the addition of stromal factors. We have examined the substrate requirements of thylakoid translocation by testing the ability of different processed forms of plastocyanin to transport in the in vitro system. Interestingly, only the full-length plastocyanin precursor, not the partially processed intermediate form, was competent for transport in this in vitro system.

Galactosyltransferases involved in galactolipid biosynthesis are located in the outer membrane of pea chloroplast envelopes.

The galactosylation steps in the biosynthesis of galactolipids involve two different enzymes; a UDP-Gal:diacylglycerol galactosyltransferase and a galactolipid:galactolipid galactosyltransferase. Previous localization studies have shown that in spinach these enzymes are located in the chloroplast envelope. Our results with peas (Pisum sativum var Laxton's Progress No. 9) confirm these results and extend the localization by providing evidence that the galactosyltransferases are in the outer membrane of the envelope. The specific activity of UDP-Gal:diacylglycerol galactosyltransferase in outer membrane preparations was 6 to 10 times greater than that exhibited by inner membrane preparations. In addition, using quantitative sodium dodecyl sulfate-polyacrylamide gel electrophoresis, it was possible to show that the UDP-Gal:diacylglycerol galactosyltransferase activity associated with inner membrane preparations could be accounted for by outer membrane contamination. It is concluded from these results that this enzyme is located predominantly, if not exclusively, in the outer membrane of the envelope. An analysis of the galactolipid products synthesized by the highly purified outer membrane showed that the galactolipid:galactolipid galactosyltransferase is also present, suggesting that this enzyme is also an outer membrane enzyme. The implication of these results is that the final assembly of galactolipids is carried out on the outer membrane of the chloroplast envelope.

Acyl-CoA Synthetase Is Located in the Outer Membrane and Acyl-CoA Thioesterase in the Inner Membrane of Pea Chloroplast Envelopes.

Both acyl-CoA synthetase and acyl-CoA thioesterase activities are present in chloroplast envelope membranes. The functions of these enzymes in lipid metabolism remains unresolved, although the synthetase has been proposed to be involved in either plastid galactolipid synthesis or the export of plastid-synthesized fatty acids to the cytoplasm. We have examined the locations of both enzymes within the two envelope membranes of pea (Pisum sativum var Laxton's Progress No. 9) chloroplasts. Inner and outer envelope membranes were purified from unfractionated envelope preparations by linear density sucrose gradient centrifugation. Acyl-CoA synthetase was located in the outer envelope membrane while acyl-CoA thioesterase was located in the inner envelope membrane. Thus, it seems unlikely that the synthetase is directly involved in galactolipid assembly. Instead, its localization supports the hypothesis that it functions in the transport of plastid-synthesized fatty acids to the endoplasmic reticulum.

Evidence that Envelope and Thylakoid Membranes from Pea Chloroplasts Lack Glycoproteins.

Envelope and thylakoid membranes from pea (Pisum sativum var. Laxton's Progress No. 9) chloroplasts were analyzed for the presence of glycoproteins using two different approaches. First, the sugar composition of delipidated membrane polypeptides was measured directly using gas chromatographic analysis. The virtual absence of sugars suggests that plastid membranes lack glycoproteins. Second, membrane polypeptides separated by sodium dodecyl sulfate gel electrophoresis were tested for reactivity toward three different lectins: Concanavalin A, Ricinus communis agglutinin, and wheat germ agglutinin. In each case, there was no reactivity between any of the lectins and the plastid polypeptides. Microsomal membranes from pea tissues were used as a positive control. Glycoproteins were readily detectable in microsomal membranes using either of the two techniques. From these results it was concluded that pea chloroplast membranes do not contain glycosylated polypeptides.

Carbohydrate structure of Sindbis virus glycoprotein E2 from virus grown in hamster and chicken cells.

Sindbis virus was used as a probe to examine glycosylation processes in two different species of cultured cells. Parallel studies were carried out analyzing the carbohydrate added to Sindbis glycoprotein E2 when the virus was grown in chicken embryo cells and BHK cells. The Pronase glycopeptides of Sindbis glycoprotein E2 were purified by a combination of ion-exchange and gel filtration chromatography. Four glycopeptides were resolved, ranging in molecular weight from 1,800 to 2,700. Structures are proposed for each of the four glycopeptides, based on data obtained by quantitative composition analyses, methylation analyses, and degradation of the glycopeptides using purified exo- and endoglycosidases. The largest three glycopeptides (S1, S2, and S3) have similar structures but differ in the extent of sialylation. All three contain N-acetylglucosamine, mannose, galactose, and fucose, in a structure similar to oligosaccharides found on other glycoproteins. Glycopeptide S1 has two residues of sialic acid, whereas glycopeptides S2 and S3 contain 1 and 0 residues of sialic acid, respectively. The smallest glycopeptide, S4, contains only N-acetyglucosamine and mannose, and is also similar to mannose-rich oligosaccharides found on other glycoproteins. Each of the complex glycopeptides (S1, S2, or S3) from virus grown in BHK cells is indistinguishable from the corresponding glycopeptides derived from virus grown in chicken cells. Glycopeptide S4 is also very similar in size, composition, and sugar linkages from virus derived from the two hosts. These results suggest that chicken cells and BHK cells have similar glycosylation mechanisms and glycosylate Sindbis glycoprotein E2 in nearly identical ways.

Comparison of the carbohydrate of Sinbis virus glycoproteins with the carbohydrate of host glycoproteins.

The carbohydrate portions of the Sindbis virus glycoproteins were compared with the carbohydrate portions of cell surface glycoproteins from uninfected host cells. Comparisons of the size of glycopeptides were made using gel filtrations. Comparisons of sugar linkages were made by methylation analysis. The conclusion was that the Sindbis carbohydrate is similar to a portion of the host carbohydrate. Thus, the Sindbis carbohydrate structures appear to be structures normally made in the uninfected host cell, but which are added to the Sindbis glycoproteins in virus-infected cells.

Characterization of a cDNA clone encoding a chloroplast-targeted Clp homologue.

Efforts to identify cDNA clones encoding chloroplastic envelope membrane proteins of Pisum sativum L. led to the isolation of a clone encoding a 92 kDa protein found in both the inner envelope membrane and the soluble fraction of chloroplasts. Sequential transcription and translation from the insert of this clone yielded a 102 kDa protein that could be imported into chloroplasts and processed to a 92 kDa form. Although the protein was identified because it reacted with antibodies to chloroplastic envelope proteins, the imported 92 kDa protein was recovered primarily in the soluble fraction of chloroplasts. The deduced amino acid sequence of this protein has strong similarity to the Clp proteins, a recently described family of highly conserved proteins present in all organisms examined to date. The physiological significance of the presence of this protein in chloroplasts is discussed.

l-Aspartate Transport into Pea Chloroplasts : Kinetic and Inhibitor Evidence for Multiple Transport Systems.

The kinetics of l-aspartate transport into pea chloroplasts was studied in the presence and absence of transport inhibitors to determine whether multiple aspartate carriers exist. Transport was measured by the silicone oil centrifugation technique. Reciprocal plots of concentration-dependent transport rates were biphasic, indicating the presence of two transport components, distinguishable on the basis of their affinity for aspartate. These transport components, called high affinity and low affinity transport could also be distinguished on the basis of their apparent substrate saturability and their sensitivity to media pH. The apparent K(m) for high affinity transport was 30 micromolar. The K(m) for low affinity transport was not determined. To test whether these transport components could also be distinguished on the basis of inhibitor sensitivity and to assess the value of inhibitors for distinguishing multiple aspartate translocators, a survey of several classes of potential inhibitors was conducted. High affinity aspartate transport was inhibited by p-chloromercuribenzenesulfonate and mersalyl, both sulfhydryl-reactive reagents; diethyl pyrocarbonate, a histidine-reactive reagent; and nigericin and carbonyl cyanide m-chlorophenylhydrazone, both ionophores. Low affinity aspartate transport was not inhibited by p-chloromercuribenzenesulfonate or nigericin, but preliminary results suggest it was sensitive to diethyl pyrocarbonate. Because the high and low affinity transport components could be distinguished not only by their sensitivity to media pH and substrate saturability, but also by their sensitivity to various inhibitors, we concluded that they may represent different transport systems or carriers.