Soluble Chloroplast Enzyme Cleaves preLHCP Made in Escherichia coli to a Mature Form Lacking a Basic N-Terminal Domain

We have investigated the specificity of a chloroplast soluble processing enzyme that cleaves the precursor of the major light-harvesting chlorophyll a/b binding protein (LHCP). The precursor of LHCP (preLHCP) was synthesized in Escherichia coli and recovered from inclusion-like bodies. It was found to be a substrate for proteolytic cleavage by the soluble enzyme in an organelle-free reaction, yielding a 25 kilodalton peptide. This peptide co-migrated during sodium dodecyl sulfate-polyacrylamide gel electrophoresis with the smaller of the forms (25 and 26 kilodalton) produced when either the E. coli-synthesized precursor, or preLHCP made in a reticulocyte lysate, was imported into chloroplasts. N-Terminal sequence analysis of the E. coli-generated precursor showed that it lacked an N-terminal methionine. N-Terminal sequencing of the 25 kilodalton peptide produced in the organelle-free reaction indicated that processing occurred between residues 40 and 41, removing a basic domain (RKTAAK) thought to be at the N-terminus of all LHCP molecules of type I associated with photosystem II. To determine if the soluble enzyme involved also cleaves other precursor polypeptides, or is specific to preLHCP, it was partially purified, and the precursors for Rubisco small subunit, plastocyanin, Rubisco activase, heat shock protein 21, and acyl carrier protein were tested as substrates. All of these precursors were cleaved by the same chromatographic peak of activity that processes preLHCP in the organelle-free reaction.     

Mutations at the transit peptide-mature protein junction separate two cleavage events during chloroplast import of the chlorophyll a/b-binding protein

We have shown previously that during in vitro import into chloroplasts, the precursor of the major light-harvesting chlorphyll a/b-binding protein (LHCP) generated from a wheat gene gives rise to two mature forms (25 and approximately 26 kDa) which are inserted into the thylakoids. However, during incubation of the LHCP precursor with a chloroplast-soluble extract in an organelle-free processing reaction, the NH2 terminus is cleaved, yielding only a 25-kDa peptide. In the present study, mutations at the transit peptide-mature protein junction were introduced in the LHCP precursor to investigate the relationship between the two peptides and the determinants of proteolytic processing. Mutant p delta 3 lacks 3 amino acids including Met34 at the primary cleavage site thought to give rise to the 26-kDa peptide. It is still processed during import and in the organelle-free reaction yielding in both assays only a 25-kDa peptide. Mutant p + 4 has 4 amino acids inserted immediately after Met34 and a proline that disrupts the alpha-helix predicted by the Garnier-Osguthorpe-Robson method (Garnier, J., Osguthorpe, D. J., and Robson, B. (1978) J. Mol. Biol. 120, 97-120) to extend through this region. Although p + 4 is imported, it is inefficiently processed; both a 25- and 26-kDa peptide are found, but at least 60% of the imported precursor remains uncleaved. Less than 5% is processed in the organelle-free assay. Replacement of the predicted alpha-helix in the mutant p + 4 alpha restores processing upon import into the chloroplast, but this mutant, which also has a 4-amino acid insert, yields only a 26-kDa peptide. p + 4 alpha is not processed in the organelle-free reaction. These results provide evidence that the two forms of LHCP obtained during import are the result of independent processing at two cleavage sites: the first site at Met34, and a second approximately 10 amino acids downstream within what has been designated the NH2 terminus of the mature protein. Whereas p delta 3 has the first site removed but retains a functional second site, in p + 4 alpha only the first site, or one very near it, is accessible to the processing enzyme during import. The conditions of the organelle-free reaction are specific for processing at only the secondary site. We discuss the implications of these findings in terms of the heterogeneity of LHCP in vivo.     

Accumulation of a light-harvesting chlorophyll a/b protein in the chloroplast grana lamellae. The lateral migration of the membrane protein precursor is independent of its processing.

The events that follow the import of pLHCPIIb, the apoprotein precursor of the major light-harvesting complex of photosystem II, were studied in intact pea chloroplasts. The distribution of the events of insertion into the membrane, and processing, to yield the mature form (LHCP) between stromal and granal lamellae regions of the thylakoids were followed. pLHCP was preferentially inserted into stromal lamellae (SL) from which it migrated to granal lamellae (GL). Migration occurred before or after processing, suggesting that migration and processing are independent of each other. When migration was slowed down, LHCP accumulated in SL. Prolonged inhibition of migration induced degradation of LHCP that had accumulated in SL, whereas inhibition of processing did not affect the migration of pLHCP into GL. A small difference in electrophoretic mobility was noted between LHCP in SL and in GL. The predominant mature form in SL migrated more slowly than LHCP from GL. When thylakoids were subjected to trypsin, all of the LHCP embedded in SL underwent cleavage, whereas up to 60% of the radioactive LHCP in GL was resistant to the enzyme. The possible implications of the differences in size and in the sensitivity to trypsin of LHCP are discussed.     

An imported thylakoid protein accumulates in the stroma when insertion into thylakoids is inhibited

The light-harvesting chlorophyll a/b protein (LHCP) is synthesized in the cytosol as a precursor (pLHCP) that is imported into chloroplasts and assembled into thylakoid membranes. Under appropriate conditions, either pLHCP or LHCP will integrate into isolated thylakoids. We have identified two situations that inhibit integration in this assay. Ionophores and uncouplers inhibited integration up to 70%. Carboxyl-terminal truncations of pLHCP also interfered with integration. A 22-residue truncation reduced integration to about 25% of control, whereas a 93 residue truncation completely abolished it. When pLHCP was imported into chloroplasts in the presence of uncouplers or when truncated forms of pLHCP were used, significant amounts of the imported proteins failed to insert into thylakoids and instead accumulated in the aqueous stroma. Accumulation of stromal LHCP occurred at uncoupler concentrations required to dissipate the trans-thylakoid proton electrochemical gradient and was enhanced at reduced levels of ATP. The latter effect may be a secondary consequence of a reduction in ATP-dependent degradation within the stroma. These results indicate that the stroma is an intermediate location in the LHCP assembly pathway and provide the first evidence for a soluble intermediate during biogenesis of a chloroplast membrane protein.     

The chlorophyll a/b-binding protein inserts into the thylakoids independent of its cognate transit peptide

In order to determine if the cognate transit peptide of the light-harvesting chlorophyll a/b-binding protein (LHCP) is essential for LHCP import into the chloroplast and proper localization to the thylakoids, it was replaced with the transit peptide of the small subunit (S) of ribulose-1,5-bisphosphate carboxylase/oxygenase, a stromal protein. Wheat LHCP and S genes were fused to make a chimeric gene coding for the hybrid precursor, which was synthesized in vitro and incubated with purified pea chloroplasts. My results show that LHCP is translocated into chloroplasts by the S transit peptide. The hybrid precursor was processed; and most importantly, mature LHCP did not remain in the stroma, but was inserted into thylakoid membranes, where it normally functions. Density gradient centrifugation showed no LHCP in the envelope fraction. Hence, the transit peptide of LHCP is not required for intraorganellar routing, and LHCP itself contains an internal signal for localization to the correct membrane compartment.     

Assembly of the barley light-harvesting chlorophyll a/b proteins in barley etiochloroplasts involves processing of the precursor on thylakoids

A barley gene encoding the major light-harvesting chlorophyll a/b-binding protein (LHCP) has been sequenced and then expressed in vitro to produce a labelled LHCP precursor (pLHCP). When barley etiochloroplasts are incubated with this pLHCP, both labelled pLHCP and LHCP are found as integral thylakoid membrane proteins, incorporated into the major pigment-protein complex of the thylakoids. The presence of pLHCP in thylakoids and its proportion with respect to labelled LHCP depends on the developmental stage of the plastids used to study the import of pLHCP. The reduced amounts of chlorophyll in a chlorophyll b-less mutant of barley does not affect the proportion of pLHCP to LHCP found in the thylakoids when import of pLHCP into plastids isolated from the mutant plants is examined. Therefore, insufficient chlorophyll during early stages of plastid development does not seem to be responsible for their relative inefficiency in assembling pLHCP. A chase of labelled pLHCP that has been incorporated into the thylakoids of intact plastids, by further incubation of the plastids with unlabelled pLHCP, reveals that the pLHCP incorporated into the thylakoids can be processed to its mature size. Our observations strongly support the hypothesis that after import into plastids, pLHCP is inserted into thylakoids and then processed to its mature size under in vivo conditions.     

Determinants for cleavage of the chlorophyll a/b binding protein precursor: a requirement for a basic residue that is not universal for chloroplast imported proteins

We demonstrate that the precursor of the major light-harvesting chlorophyll a/b binding protein (LHCP of Photosystem II), encoded by a Type I gene, contains distinct determinants for processing at two sites during in vitro import into the chloroplast. Using precursors from both pea and wheat, it is shown that primary site processing, and release of a approximately 26-kD peptide, depends on an amino-proximal basic residue. Substitution of an arginine at position -4 resulted in an 80% reduction in processing, with the concomitant accumulation of a high molecular weight intermediate. Cleavage occurred normally when arginine was changed to lysine. The hypothesis that a basic residue is a general requirement for transit peptide removal was tested. We find that the precursors for the small subunit of Rubisco and Rubisco activase do not require a basic residue within seven amino acids of the cleavage site for maturation. In the wheat LHCP precursor, determinants for efficient cleavage at a secondary site were identified carboxy to the primary site, beyond what is traditionally called the transit peptide, within the sequence ala-lys-ala-lys (residues 38-41). Introduction of this sequence into the pea precursor, which has the residues thr-thr-lys-lys in the corresponding position, converted it to a substrate with an efficiently recognized secondary site. Our results indicate that two different forms of LHCP can be produced with distinct NH2-termini by selective cleavage of a single precursor polypeptide.     

Processing of a wheat light-harvesting chlorophyll a/b protein precursor by a soluble enzyme from higher plant chloroplasts

A processing activity has been identified in higher plant chloroplasts that cleaves the precursor of the light-harvesting chlorophyll a/b- binding protein (LHCP). A wheat LHCP gene previously characterized (Lamppa, G.K., G. Morelli, and N.-H. Chua, 1985. Mol. Cell Biol. 5:1370- 1378) was used to synthesize RNA and subsequently the labeled precursor polypeptide in vitro. Incubation of the LHCP precursors with a soluble extract from lysed chloroplasts, after removal of the thylakoids and membrane vesicles, resulted in the release of a single 25-kD peptide. In contrast, when the LHCP precursors were used in an import reaction with intact pea or wheat chloroplasts, two forms (25 and 26 kD) of mature LHCP were found. The peptide released by the processing activity in the organelle-free assay comigrated with the lower molecular mass form of mature LHCP produced during import. Properties of the processing activity suggest that it is an endopeptidase. Chloroplasts from both pea and wheat, two divergent higher plants, contain the processing enzyme, suggesting its physiological importance in LHCP assembly into the thylakoids. We discuss the implications of LHCP precursor processing by a soluble enzyme that may be in the stromal compartment.     

Loss of efficient import and thylakoid insertion due to N- and C-terminal deletions in the light-harvesting chlorophyll a/b binding protein.

C-terminally truncated precursors of wheat light-harvesting chlorophyll a/b binding protein (LHCP) were synthesized to investigate the origin of the two forms (about 25 kD and 26 kD) of the mature protein observed upon in vitro import into the chloroplast. Precursors p delta 13 and p delta 27, lacking 13 and 27 amino acids, respectively, were successfully imported, and both gave rise to two smaller forms proportional to the size of their deletions. These results demonstrate that there are two N-terminal sites that are cleaved during import of the LHCP precursor, undoubtedly contributing to the heterogeneity of LHCP found in vivo. Significantly, p delta 27 yielded only 50% of mature LHCP when compared with wild type. Although the products of p delta 27 import were localized to the thylakoids, in contrast to p delta 13 they were not correctly inserted into the membranes, indicating that residues essential for this step are missing. p delta 27 is distinguished from p delta 13 by lacking the carboxy end of a domain highly conserved between LHCP of photosystems II and I. Other specific precursor mutants with larger C-terminal deletions were not efficiently transported into the organelle in time course experiments, nor did they insert directly into the thylakoids using chloroplast lysates, in an assay independent of translocation across the envelope. In addition, the mutant p delta 18n, lacking the first 18 amino acids of mature LHCP, was only found bound to the chloroplast envelope. However, both p delta 18n and the mature protein, i.e., LHCP, synthesized in vitro without its 34-amino acid transit peptide inserted into the thylakoids in chloroplast lysates. The overall conformation of the mutant precursor polypeptides was probed using the chloroplast soluble processing enzyme in an organelle-free reaction optimized for the LHCP precursor and the more general protease trypsin. A tightly folded, protease-resistant conformation was not apparent to explain the loss of efficient import.     

Requirement for three membrane-spanning alpha-helices in the post-translational insertion of a thylakoid membrane protein.

The insertion of a protein into a lipid bilayer usually involves a short signal sequence and can occur either during or after translation. A light-harvesting chlorophyll a/b-binding protein (LHCP) is synthesized in the cytoplasm of plant cells as a precursor and is post-translationally imported into chloroplasts where it subsequently inserts into the thylakoid membrane. Only mature LHCP is required for insertion into the thylakoid. To define which sequences of the mature protein are necessary and sufficient for thylakoid integration, fusion and deletion proteins and proteins with internal rearrangements were synthesized and incubated with isolated thylakoids and stroma. No evidence is found for the existence of a short signal sequence within LHCP, and, with the exception of the amino terminus and a short lumenal loop, the entire mature protein with consecutively ordered alpha-helices is required for insertion into thylakoid membranes. The addition of positive charges into stromal but not lumenal segments permits the insertion of mutant LHCPs into isolated thylakoids. Replacement of the LHCP transit peptide with the transit peptide from plastocyanin has no effect on LHCP insertion and does not restore insertion of the lumenal charge addition mutants.     

Processing of the Precursors for the Light-Harvesting Chlorophyll-Binding Proteins of Photosystem II and Photosystem I during Import and in an Organelle-Free Assay

We have investigated whether the precursors for the light-harvesting chlorophyll a/b binding proteins (LHCP) of photosystems II and I (PSII and PSI) are cleavable substrates in an organelle-free reaction, and have compared the products with those obtained during in vitro import into chloroplasts. Representatives from the tomato (Lycopersicon esculentum) LHCP family were analyzed. The precursor for LHCP type I of PSII (pLHCPII-1), encoded by the tomato gene Cab3C, was cleaved at only one site in the organelle-free assay, but two sites were recognized during import, analogous to our earlier results with a wheat precursor for LHCPII-1. The relative abundance of the two peptides produced was investigated during import of pLHCPII-1 into chloroplasts isolated from plants greened for 2 or 24 hours. In contrast to pLHCPII-1, the precursors for LHCP type II and III of PSI were cleaved in both assays, giving rise to a single peptide. The precursor for LHCP type I of PSI, encoded by gene Cab6A, yielded two peptides of 23.5 and 21.5 kilodaltons during import, whereas in the organelle-free assay only the 23.5 kilodalton peptide was found. N-terminal sequence analysis of this radiolabeled peptide has tentatively identified the site cleaved in the organelle-free assay between met40 and ser41 of the precursor.     

Functional and mutational analysis of the light-harvesting chlorophyll a/b protein of thylakoid membranes

The precursor for a Lemna light-harvesting chlorophyll a/b protein (pLHCP) has been synthesized in vitro from a single member of the nuclear LHCP multigene family. We report the sequence of this gene. When incubated with Lemna chloroplasts, the pLHCP is imported and processed into several polypeptides, and the mature form is assembled into the light-harvesting complex of photosystem II (LHC II). The accumulation of the processed LHCP is enhanced by the addition to the chloroplasts of a precursor and a co-factor for chlorophyll biosynthesis. Using a model for the arrangement of the mature polypeptide in the thylakoid membrane as a guide, we have created mutations that lie within the mature coding region. We have studied the processing, the integration into thylakoid membranes, and the assembly into light-harvesting complexes of six of these deletions. Four different mutant LHCPs are found as processed proteins in the thylakoid membrane, but only one appears to have an orientation in the membrane that is similar to that of the wild type. No mutant LHCP appears in LHC II. The other two mutant LHCPs cannot be detected within the chloroplasts. We conclude that stable complex formation is not required for the processing and insertion of altered LHCPs into the thylakoid membrane. We discuss the results in light of our model.     

Chloroplast precursor proteins compete to form early import intermediates in isolated pea chloroplasts

In order to ascertain whether there is one site for the import of precursor proteins into chloroplasts or whether different precursor proteins are imported via different import machineries, chloroplasts were incubated with large quantities of the precursor of the 33 kDa subunit of the oxygen-evolving complex (pOE33) or the precursor of the light-harvesting chlorophyll a/b-binding protein (pLHCP) and tested for their ability to import a wide range of other chloroplast precursor proteins. Both pOE33 and pLHCP competed for import into chloroplasts with precursors of the stromally-targeted small subunit of Rubisco (pSSu), ferredoxin NADP(+) reductase (pFNR) and porphobilinogen deaminase; the thylakoid membrane proteins LHCP and the Rieske iron-sulphur protein (pRieske protein); ferrochelatase and the gamma subunit of the ATP synthase (which are both associated with the thylakoid membrane); the thylakoid lumenal protein plastocyanin and the phosphate translocator, an integral membrane protein of the inner envelope. The concentrations of pOE33 or pLHCP required to cause half-maximal inhibition of import ranged between 0.2 and 4.9 microM. These results indicate that all of these proteins are imported into the chloroplast by a common import machinery. Incubation of chloroplasts with pOE33 inhibited the formation of early import intermediates of pSSu, pFNR and pRieske protein.     

Determinants for removal and degradation of transit peptides of chloroplast precursor proteins

The stromal processing peptidase (SPP) cleaves a large diversity of chloroplast precursor proteins, removing an N-terminal transit peptide. We predicted previously that this key step of the import pathway is mediated by features of the transit peptide that determine precursor binding and cleavage followed by transit peptide conversion to a degradable substrate. Here we performed competition experiments using synthesized oligopeptides of the transit peptide of ferredoxin precursor to investigate the mechanism of these processes. We found that binding and processing of ferredoxin precursor depend on specific interactions of SPP with the region consisting of the C-terminal 12 residues of the transit peptide. Analysis of four other precursors suggests that processing depends on the same region, although their transit peptides are highly divergent in primary sequence and length. Upon processing, SPP terminates its interaction with the transit peptide by a second cleavage, converting it to a subfragment form. From the competition experiments we deduce that SPP releases a subfragment consisting of the transit peptide without its original C terminus. Interestingly, examination of the ATP-dependent metallopeptidase activity responsible for degradation of transit peptide subfragments suggests that it may recognize other unrelated peptides and, hence, act separately from SPP as a novel stromal oligopeptidase.     

Chloroplast Import of Light-Harvesting Chlorophyll a/b-Proteins with Different Amino Termini and Transit Peptides

We have previously isolated and sequenced two genes encoding light-harvesting chlorophyll a/b-proteins (LHCP) from Lemna gibba. One of these, AB30, encodes a protein that is highly homologous to LHCP sequences reported from other species, but the second, AB19, encodes a protein that has a transit peptide and first 12 amino-terminal residues of the mature protein that are substantially different. Despite these differences, we can demonstrate that AB19 encoded protein synthesized in vitro can be imported into isolated chloroplasts, and we provide evidence that at least some of the imported molecules are assembled into the light-harvesting complex of photosystem II. Thus, our results are consistent with the possibility that there are two functional forms of LHCP.     

Partitioning of malate dehydrogenase isoenzymes into glyoxysomes, mitochondria, and chloroplasts

Malate dehydrogenase isoenzymes catalyzing the oxidation of malate to oxaloacetate are highly active enzymes in mitochondria, in peroxisomes, in chloroplasts, and in the cytosol. Determination of the primary structure of the isoenzymes has disclosed that they are encoded in different nuclear genes. All three organelle-targeted malate dehydrogenases are synthesized with an amino terminal extension that is cleaved off in connection with the import of the enzyme precursor into the organelle. The sequence of the 27 amino acids of the mitochondrial transit peptide is unrelated to the 37-residue glyoxysomal transit peptide, which in turn is entirely different in sequence from the 57-residue chloroplastic transit peptide. With the exception of malate dehydrogenase and 3-ketoacyl thiolase, peroxisomal enzymes are synthesized without transit peptides and are frequently translocated into the organelle with a peroxisomal targeting signal consisting of a conserved tripeptide at the carboxy terminus of the protein. Based on the observation that this tripeptide (Ala-His-Leu) occurs in the transit peptides of glyoxysomal malate dehydrogenase and peroxisomal 3-ketoacyl thiolase, the possible significance of amino terminal transit peptides for peroxisome import is discussed.     

Transport of proteins into chloroplasts

The import of cytoplasmically synthesized proteins into chloroplasts involves an interaction between at least two components; the precursor protein, and the import apparatus in the chloroplast envelope membrane. This review summarizes the information available about each of these components. Precursor proteins consist of an amino terminal transit peptide attached to a passenger protein. Transit peptides from various precurosrs are diverse with respect to length and amino acid sequence; analysis of their sequences has not revealed insight into their mode of action. A variety of foreign passenger proteins can be imported into chloroplasts when a transit peptide is present at the amino terminus. However, foreign passenger proteins are not imported as efficiently as natural passenger proteins, and some chimeric precursor proteins are not imported into chloroplasts at all. Therefore, the passenger protein, as well as the transit peptide, influences the import process. Import begins by binding of the precursor to the chloroplast surface. It has been suggested that this binding is mediated by a receptor, but evidence to support this hypothesis remains incomplete and a receptor protein has not yet been characterized. Protein translocation requires energy derived from ATP hydrolysis, although there are conflicting reports as to where hydrolysis occurs and it is unclear how this energy is utilized. The mechanism(s) whereby proteins are translocated across either the two envelope membranes or the thylakoid membrane is not known.Abbreviations EPSP 5-enolpyruvyulshikimate-3-phosphate - LHCP Chlorophyll a/b binding protein of the light-harvesting complex - NPT-II Neomycin phosphotransferase II - PC Plastocyanin - Pr Precursor - Rubisco Ribulose-1,5,-bisphosphate carboxylase/oxygenase - SS Small subunit of Rubisco     

The major light-harvesting complex of Photosystem II: aspects of its molecular and cell biology

The light-harvesting complex of photosystem II (LHC II) contains one major (LHC IIb) and at least three minor chlorophyll-protein components. The apoproteins of LHC IIb (LHCP) are encoded by nuclear genes and synthesized in the cytoplasm as a higher molecular weight precursor(s) (pLHCP). Several genes coding for pLHCP have been cloned from various higher plant species. The expression of these genes is dependent upon a variety of factors such as light, the developmental stage of the plastids and the plant. After its synthesis in the cytoplasm, pLHCP is imported into plastids, inserted into thylakoids, processed to its mature form, and assembled into LHC IIb. The pathway of assembly of LHC IIb in the thylakoid membranes is currently being investigated in several laboratories. We present a model that gives some details of the steps in the assembly process. Many of the steps involved in the synthesis and assembly are dependent on light and the stage of plastid development.Abbreviations PS Photosystem - LHC II Light-harvesting complex of PS II - LHCP Apoproteins of LHC IIb - pLHCP Precursor of LHCP - PAGE Polyacrylamide gel electrophoresis     

Structure of a slow processing precursor penicillin acylase from Escherichia coli reveals the linker peptide blocking the active-site cleft

Penicillin G acylase is a periplasmic protein, cytoplasmically expressed as a precursor polypeptide comprising a signal sequence, the A and B chains of the mature enzyme (209 and 557 residues respectively) joined by a spacer peptide of 54 amino acid residues. The wild-type AB heterodimer is produced by proteolytic removal of this spacer in the periplasm. The first step in processing is believed to be autocatalytic hydrolysis of the peptide bond between the C-terminal residue of the spacer and the active-site serine residue at the N terminus of the B chain. We have determined the crystal structure of a slowly processing precursor mutant (Thr263Gly) of penicillin G acylase from Escherichia coli, which reveals that the spacer peptide blocks the entrance to the active-site cleft consistent with an autocatalytic mechanism of maturation. In this mutant precursor there is, however, an unexpected cleavage at a site four residues from the active-site serine residue. Analyses of the stereochemistry of the 260-261 bond seen to be cleaved in this precursor structure and of the 263-264 peptide bond have suggested factors that may govern the autocatalytic mechanism.     

Maturation and subcellular compartmentation of potato starch phosphorylase.

The subcellular localization and maturation of starch phosphorylase (EC 2.4.1.1) was studied in developing potato tubers. The enzyme is localized inside the stroma of amyloplasts in young tubers, whereas in mature tubers it is found within the cytoplasm in the immediate vicinity of the plastids. A phosphorylase cDNA clone was isolated and used in RNA gel blot experiments to demonstrate that phosphorylase mRNAs are of the same size and abundance in both young and mature tubers. In vitro translation of mRNAs followed by immunoprecipitation with a phosphorylase antiserum indicates that the enzyme is synthesized as a higher molecular weight precursor in both young and mature tubers. The presence of a transit peptide at the N terminus of the protein was confirmed by the sequencing of the phosphorylase cDNA clone. The transit peptide has several structural features common to transit peptides of chloroplast proteins but contains a surprisingly large number of histidine residues. The mature form of the enzyme is present in both young and mature tubers, suggesting that a similar processing of the transit peptide may take place in two different subcellular locations.