Light-dependent assembly of ribulose-1,5-bisphosphate carboxylase

Chaperonin-assisted protein folding: a chronologue

This chronologue seeks to document the discovery and development of an understanding of oligomeric ring protein assemblies known as chaperonins that assist protein folding in the cell. It provides detail regarding genetic, physiologic, biochemical, and biophysical studies of these ATP-utilizing machines from both in vivo and in vitro observations. The chronologue is organized into various topics of physiology and mechanism, for each of which a chronologic order is generally followed. The text is liberally illustrated to provide firsthand inspection of the key pieces of experimental data that propelled this field. Because of the length and depth of this piece, the use of the outline as a guide for selected reading is encouraged, but it should also be of help in pursuing the text in direct order.

Rubisco Assembly in the Chloroplast

Ribulose-1,5-bisphosphate carboxylase/oxygenase (Rubisco) catalyzes the rate-limiting step in the Calvin-Benson cycle, which transforms atmospheric carbon into a biologically useful carbon source. The slow catalytic rate of Rubisco and low substrate specificity necessitate the production of high levels of this enzyme. In order to engineer a more efficient plant Rubisco, we need to better understand its folding and assembly process. Form I Rubisco, found in green algae and vascular plants, is a hexadecamer composed of 8 large subunits (RbcL), encoded by the chloroplast genome and 8 small, nuclear-encoded subunits (RbcS). Unlike its cyanobacterial homolog, which can be reconstituted in vitro or in E. coli, assisted by bacterial chaperonins (GroEL-GroES) and the RbcX chaperone, biogenesis of functional chloroplast Rubisco requires Cpn60-Cpn20, the chloroplast homologs of GroEL-GroES, and additional auxiliary factors, including Rubisco accumulation factor 1 (Raf1), Rubisco accumulation factor 2 (Raf2) and Bundle sheath defective 2 (Bsd2). The discovery and characterization of these factors paved the way for Arabidopsis Rubisco assembly in E. coli. In the present review, we discuss the uniqueness of hetero-oligomeric chaperonin complex for RbcL folding, as well as the sequential or concurrent actions of the post-chaperonin chaperones in holoenzyme assembly. The exact stages at which each assembly factor functions are yet to be determined. Expression of Arabidopsis Rubisco in E. coli provided some insight regarding the potential roles for Raf1 and RbcX in facilitating RbcL oligomerization, for Bsd2 in stabilizing the oligomeric core prior to holoenzyme assembly, and for Raf2 in interacting with both RbcL and RbcS. In the long term, functional characterization of each known factor along with the potential discovery and characterization of additional factors will set the stage for designing more efficient plants, with a greater biomass, for use in biofuels and sustenance.

Dynamic Complexes in the Chaperonin-Mediated Protein Folding Cycle

The GroEL–GroES chaperonin system is probably one of the most studied chaperone systems at the level of the molecular mechanism. Since the first reports of a bacterial gene involved in phage morphogenesis in 1972, these proteins have stimulated intensive research for over 40 years. During this time, detailed structural and functional studies have yielded constantly evolving concepts of the chaperonin mechanism of action. Despite of almost three decades of research on this oligomeric protein, certain aspects of its function remain controversial. In this review, we highlight one central aspect of its function, namely, the active intermediates of its reaction cycle, and present how research to this day continues to change our understanding of chaperonin-mediated protein folding.

Chaperone-assisted Post-translational Transport of Plastidic Type I Signal Peptidase 1

Type I signal peptidase (SPase I) is an integral membrane Ser/Lys protease with one or two transmembrane domains (TMDs), cleaving transport signals off translocated precursor proteins. The catalytic domain of SPase I folds to form a hydrophobic surface and inserts into the lipid bilayers at the trans-side of the membrane. In bacteria, SPase I is targeted co-translationally, and the catalytic domain remains unfolded until it reaches the periplasm. By contrast, SPases I in eukaryotes are targeted post-translationally, requiring an alternative strategy to prevent premature folding. Here we demonstrate that two distinct stromal components are involved in post-translational transport of plastidic SPase I 1 (Plsp1) from Arabidopsis thaliana, which contains a single TMD. During import into isolated chloroplasts, Plsp1 was targeted to the membrane via a soluble intermediate in an ATP hydrolysis-dependent manner. Insertion of Plsp1 into isolated chloroplast membranes, by contrast, was found to occur by two distinct mechanisms. The first mechanism requires ATP hydrolysis and the protein conducting channel cpSecY1 and was strongly enhanced by exogenously added cpSecA1. The second mechanism was independent of nucleoside triphosphates and proteinaceous components but with a high frequency of mis-orientation. This unassisted insertion was inhibited by urea and stroma extract. During import-chase assays using intact chloroplasts, Plsp1 was incorporated into a soluble 700-kDa complex that co-migrated with the Cpn60 complex before inserting into the membrane. The TMD within Plsp1 was required for the cpSecA1-dependent insertion but was dispensable for association with the 700-kDa complex and also for unassisted membrane insertion. These results indicate cooperation of Cpn60 and cpSecA1 for proper membrane insertion of Plsp1 by cpSecY1.

Nonsense mutations in the Chlamydomonas chloroplast gene that codes for the large subunit of ribulosebisphosphate carboxylase/oxygenase

The Chlamydomonas reinhardtii chloroplast mutants 18-5B and 18-7G lack both the chloroplast-encoded large subunit and nuclear-encoded small subunit of the chloroplast enzyme ribulose-1,5-bisphosphate carboxylase/oxygenase (EC 4.1.1.39). A chloroplast intergenic-suppression model has been postulated to account for the genetic instability of 18-5B revertants. Here, we have determined the molecular basis of the 18-5B and 18-7G mutants. They contain nonsense mutations close to the 3' and 5' ends of their large-subunit genes, respectively. Pulse-chase experiments revealed that the 18-5B mutant produces a truncated large subunit that is unstable. In connection with previous experiments, this work identifies nonsense suppression in the chloroplast. Small subunits are also synthesized but then degraded in the mutants. Thus, the coordinated absence of subunits is achieved through degradation of the small subunit in the specific absence of the large subunit.

Pathway of assembly of ribulosebisphosphate carboxylase/oxygenase from Anabaena 7120 expressed in Escherichia coli

We have placed the genes encoding ribulose-bisphosphate carboxylase/oxygenase from the Anabaena 7120 operon under transcriptional control of the lac promoter carried on the Escherichia coli plasmid pUC19. The genes encoding both the large and small subunit polypeptides (rbcL and rbcS) are transcribed and translated so that approximately 0.6% of the soluble protein in E. coli extracts is a fully functional holoenzyme with a sedimentation coefficient of approximately 18S, which contains stoichiometric amounts of the two subunits. However, expression of the large subunit polypeptide vastly exceeds that of the small subunit because the majority of transcripts terminate in the intergenic region between the rbcL and rbcS genes. As a result, excess large subunit is synthesized and accumulates in E. coli as an insoluble and catalytically inactive form. Because small subunit is found only in the high molecular weight soluble form of ribulosebisphosphate carboxylase/oxygenase, we propose that the small subunit promotes assembly of the hexadecameric form of the enzyme via heterodimers of large and small subunits.

Binding of a transition state analog to newly synthesized Rubisco

Radioactive amino acids, when added to isolated pea chloroplasts or chloroplast extracts engaged in protein synthesis, are incorporated into Rubisco large subunits that co-migrate with native Rubisco during nondenaturing electrophoresis. We have added the transition state analog 2'-carboxyarabinitol bisphosphate (CABP) to chloroplast extracts after in organello or in vitro incorporation of radioactive amino acids into Rubisco large subunits. Upon addition of CABP the radioactive bands co-migrating with native Rubisco undergo a readily detected shift in electrophoretic mobility just as the native enzyme, thus demonstrating the ability of the newly assembled molecules to interact with this transition state analog.

From chloroplasts to chaperones: how one thing led to another

Two lessons I have learned during my research career are the importance of following up unexpected observations and realizing that the most obvious interpretation of such observations can be rational but wrong. When you carry out an experiment there is usually an expectation that the result will fall within a range of predictable outcomes, and it is natural to feel pleased when this turns out to be the case. In my view this response is a mistake. What you should be hoping for is a puzzling result that was not anticipated since with persistence and luck further experiments may uncover something new. In this article I give a personal account of how studies of the synthesis of proteins by isolated intact chloroplasts from pea leaves eventually led to the discovery of the chaperonins and the formulation of the general concept of the molecular chaperone function that is now seen to be a fundamental aspect of how all cells work.

Future prospects for genetic manipulation of Rubisco

Recent advances in the development of techniques for the manipulation of gene structure in vitro and genetic transformation of plants have brought the goal of directed genetic modification of RuBP carboxylase-oxygenase (Rubisco) within grasp. Genes from both prokaryotic and eukaryotic species have been cloned, sequenced and expressed in Escherichia coli , and in several instances this has resulted in the production of large quantities of fully functional enzyme. Several specifically-modified enzymes have been produced by site-directed mutagenesis of a cloned gene and the effects of the mutations evaluated following expression of the modified genes in E. coli . Thus, there are no major technical barriers to the creation and analysis of modified enzymes. A number of new opportunities now exist to explore the structural basis of naturally occurring differences in kinetic constants of the enzymes from diverse taxonomic sources. The recent report of chloroplast transformation mediated by the Ti plasmid has also raised the possibility that, if useful natural variation can be identified, genes for both the large and small subunits of the enzyme may eventually be transferred between species. However, the opportunities for rational application of mutagenesis in vitro in the creation of useful or informative variants of the enzyme is currently limited by lack of information about tertiary structure and the role of specific residues in catalysis.

Expression of cyanobacterial and higher-plant ribulose 1,5-bisphosphate carboxylase genes in Escherichia coli

Expression strategies for the synthesis of higher-plant and cyanobacterial RuBP carboxylase genes in Escherichia coli have been developed to facilitate the study of the assembly pathway and properties of the enzyme’s large (L) and small (S) subunit proteins. The genes for the L and S subunits of the RuBP carboxylase of wheat and of a cyanobacterium, Synechococcus 6301 have been cloned into bacteriophage and plasmid vectors such that they are transcribed and translated in E. coli. To date no RuBP carboxylase activity has been detected in extracts prepared from E. coli cells synthesizing the wheat L and S subunits, although both gene products were present and soluble. Sucrose gradient analysis of cell extracts from E. coli synthesizing both L and S demonstrated that the soluble wheat L polypeptide was present as a large protein aggregate that contained no S subunits. With the cloned cyanobacterial genes, RuBP carboxylase activity could be recovered in E. coli cell extracts when the L and S gene products were synthesized from genes present on the same, or separate, replicons. Solubility and sedimentation studies of the cyanobacterial L subunits synthesized in the absence of S showed that the L subunit was soluble and present in E. coli as an L 8 structure. The E. coli extracts containing only the L subunit exhibited no detectable RuBP carboxylase activity. Infection of the E. coli cells containing L subunits with an M13 phage expressing the cyanobacterial S gene led to the assembly of functional RuBP carboxylase in these cells. This demonstrates the essential role of the S subunit in allowing the formation of an active enzyme.

Molecular chaperones and protein folding in plants

Protein folding in vivo is mediated by an array of proteins that act either as 'foldases' or 'molecular chaperones'. Foldases include protein disulfide isomerase and peptidyl prolyl isomerase, which catalyze the rearrangement of disulfide bonds or isomerization of peptide bonds around Pro residues, respectively. Molecular chaperones are a diverse group of proteins, but they share the property that they bind substrate proteins that are in unstable, non-native structural states. The best understood chaperone systems are HSP70/DnaK and HSP60/GroE, but considerable data support a chaperone role for other proteins, including HSP100, HSP90, small HSPs and calnexin. Recent research indicates that many, if not all, cellular proteins interact with chaperones and/or foldases during their lifetime in the cell. Different chaperone and foldase systems are required for synthesis, targeting, maturation and degradation of proteins in all cellular compartments. Thus, these diverse proteins affect an exceptionally broad array of cellular processes required for both normal cell function and survival of stress conditions. This review summarizes our current understanding of how these proteins function in plants, with a major focus on those systems where the most detailed mechanistic data are available, or where features of the chaperone/foldase system or substrate proteins are unique to plants.

Molecular chaperones and protein folding in plants

Protein folding in vivo is mediated by an array of proteins that act either as 'foldases' or 'molecular chaperones'. Foldases include protein disulfide isomerase and peptidyl prolyl isomerase, which catalyze the rearrangement of disulfide bonds or isomerization of peptide bonds around Pro residues, respectively. Molecular chaperones are a diverse group of proteins, but they share the property that they bind substrate proteins that are in unstable, non-native structural states. The best understood chaperone systems are HSP70/DnaK and HSP60/GroE, but considerable data support a chaperone role for other proteins, including HSP100, HSP90, small HSPs and calnexin. Recent research indicates that many, if not all, cellular proteins interact with chaperones and/or foldases during their lifetime in the cell. Different chaperone and foldase systems are required for synthesis, targeting, maturation and degradation of proteins in all cellular compartments. Thus, these diverse proteins affect an exceptionally broad array of cellular processes required for both normal cell function and survival of stress conditions. This review summarizes our current understanding of how these proteins function in plants, with a major focus on those systems where the most detailed mechanistic data are available, or where features of the chaperone/foldase system or substrate proteins are unique to plants.

Functional characterization of the higher plant chloroplast chaperonins

The higher plant chloroplast chaperonins (ch-cpn60 and ch-cpn10) have been purified and their structural/functional properties examined. In all plants surveyed, both proteins were constitutively expressed, and only modest increases in their levels were detected upon heat shock. Like GroEL and GroES of Escherichia coli, the chloroplast chaperonins can physically interact with each other. The asymmetric complexes that form in the presence of ADP are "bullet-shaped" particles that likely consist of 1 mol each of ch-cpn60 and ch-cpn10. The purified ch-cpn60 is a functional molecular chaperone. Under "nonpermissive" conditions, where spontaneous folding was not observed, it was able to assist in the refolding of two different target proteins. In both cases, successful partitioning to the native state also required ATP hydrolysis and chaperonin 10. Surprisingly, however, the "double-domain" ch-cpn10, comprised of unique 21-kDa subunits, was not an obligatory co-chaperonin. Both GroES and a mammalian mitochondrial homolog were equally compatible with the ch-cpn60. Finally, the assisted-folding reaction mediated by the chloroplast chaperonins does not require K+ ions. Thus, the K(+)-dependent ATPase activity that is observed with other known groEL homologs is not a universal property of all chaperonin 60s.

Spinach chloroplast cpn21 co-chaperonin possesses two functional domains fused together in a toroidal structure and exhibits nucleotide-dependent binding to plastid chaperonin 60

Chloroplasts contain a 21-kDa co-chaperonin polypeptide (cpn21) formed by two GroES-like domains fused together in tandem. Expression of a double-domain spinach cpn21 in Escherichia coli groES mutant strains supports growth of bacteriophages lambda and T5, and will also suppress a temperature-sensitive growth phenotype of a groES619 strain. Each domain of cpn21 expressed separately can function independently to support bacteriophage lambda growth, and the N-terminal domain will additionally suppress the temperature-sensitive growth phenotype. These results indicate that chloroplast cpn21 has two functional domains, either of which can interact with GroEL in vivo to facilitate bacteriophage morphogenesis. Purified spinach cpn21 has a ring-like toroidal structure and forms a stable complex with E. coli GroEL in the presence of ADP and is functionally interchangeable with bacterial GroES in the chaperonin-facilitated refolding of denatured ribulose-1,5-bisphosphate carboxylase. Cpn21 also inhibits the ATPase activity of GroEL. Cpn21 binds with similar efficiency to both the alpha and beta subunits of spinach cpn60 in the presence of adenine nucleotides, with ATP being more effective than ADP. The tandemly fused domains of cpn21 evolved early and are present in a wide range of photosynthetic eukaryotes examined, indicating a high degree of conservation of this structure in chloroplasts.

Identification, characterization, and DNA sequence of a functional "double" groES-like chaperonin from chloroplasts of higher plants

Chloroplasts of higher plants contain a nuclear-encoded protein that is a functional homolog of the Escherichia coli chaperonin 10 (cpn10; also known as groES). In pea (Pisum sativum), chloroplast cpn10 was identified by its ability to (i) assist bacterial chaperonin 60 (cpn60; also known as groEL) in the ATP-dependent refolding of chemically denatured ribulose-1,5-bisphosphate carboxylase and (ii) form a stable complex with bacterial cpn60 in the presence of Mg.ATP. The subunit size of the pea protein is approximately 24 kDa--about twice the size of bacterial cpn10. A cDNA encoding a spinach (Spinacea oleracea) chloroplast cpn10 was isolated, sequenced, and expressed in vitro. The spinach protein is synthesized as a higher molecular mass precursor and has a typical chloroplast transit peptide. Surprisingly, however, attached to the transit peptide is a single protein, comprised of two distinct cpn10 molecules in tandem. Moreover, both halves of this "double" cpn10 are highly conserved at a number of residues that are present in all cpn10s that have been examined. Upon import into chloroplasts the spinach cpn10 precursor is processed to its mature form of approximately 24 kDa. N-terminal amino acid sequence analysis reveals that the mature pea and spinach cpn10 are identical at 13 of 21 residues.

Synthesis and assembly of large subunits into ribulose bisphosphate carboxylase/oxygenase in chloroplast extracts

We have developed a new system for the in vitro synthesis of large subunits and their assembly into ribulose bisphosphate carboxylase oxygenase (Rubisco) holoenzyme in extracts of higher plant chloroplasts. This differs from previously described Rubisco assembly systems because the translation of the large subunits occurs in chloroplast extracts as opposed to isolated intact chloroplasts, and the subsequent assembly of large subunits into holoenzyme is completely dependent upon added small subunits. Amino acid incorporation in this system displayed the characteristics previously reported for chloroplast-based translation systems. Incorporation was sensitive to chloramphenicol or RNase but resistant to cycloheximide, required magnesium, and was stimulated by nucleotides. The primary product of this system was the large subunit of Rubisco. However, several lower molecular weight polypeptides were formed. These were structurally related to the Rubisco large subunit. The initiation inhibitor aurintricarboxylic acid (ATA) decreased the amount of lower molecular weight products accumulated. The accumulation of completed large subunits was only marginally reduced in the presence of ATA. The incorporation of newly synthesized large subunits into Rubisco holoenzyme occurred under conditions previously identified as optimal for the assembly of in organello-synthesized large subunits and required the addition of purified small subunits.

Protein folding and chaperonins

The folding of polypeptide chains in cells, following either translation or translocation through membranes, must take place under conditions of extremely high protein concentrations. In addition, folding into a correct structure must occur in the presence of other rapidly folding species, and at temperatures known to destabilize aggregation-prone folding intermediates. To facilitate folding in vivo, molecular chaperones have evolved that stabilize protein folding intermediates, thus partitioning them towards a pathway leading to the native state rather than forming inactive aggregated structures.

Photoaffinity Labeling of Mature and Precursor Forms of the Small Subunit of Ribulose-1,5-Bisphosphate Carboxylase/Oxygenase after Expression in Escherichia coli

The small subunit (SSU) of ribulose-1,5-bisphosphate carboxylase/oxygenase (Rubisco) possesses a binding site that can be photoaffinity labeled with [(32)P]8-azidoadenosine 5' triphosphate (N(3)ATP). In the present study, photoaffinity labeling was used to compare the nucleotide analog binding properties of SSU in the Rubisco holoenzyme complex (holoE SSU) with the properties of isolated SSU and the precursor form (pSSU) that contains a transit peptide. To facilitate these studies, the complete coding regions of tobacco (Nicotiana tabacum L.) SSU and pSSU were cloned into pET expression vectors and the polypeptides were synthesized in Escherichia coli. Protein import studies showed that cloned pSSU polypeptides were imported into intact chloroplasts, where they were processed to the mature form and assembled into the Rubisco holoenzyme. Cloned SSU and pSSU isolated from E. coli were photoaffinity labeled with N(3)ATP. The apparent K(d) value for SSU and pSSU, 18 micromolar N(3)ATP, was identical to the value determined for holoE SSU. However, differences in photolabeling between cloned SSU or pSSU and holoE SSU were apparent in the level of protection afforded by ATP and UTP, in the response of photolabeling to free Mg(2+), and in the higher photolabeling efficiency that characterized the cloned SSU. Treatment of the Rubisco holoenzyme with a concentration of urea sufficient to disassociate the subunits markedly increased photoincorporation into SSU, indicating that intersubunit associations within the holoenzyme complex may be the major factor influencing photolabeling efficiency of SSU. Thus, differences in SSU conformation between the isolated and assembled states affect photolabeling efficiency and other nucleotide analog binding properties of the SSU, but not the apparent affinity for N(3)ATP.

GroEL-related molecular chaperones are present in the cytosol of oat cells

In eukaryotic cells GroEL-related molecular chaperones (cpn 60) are considered to be restricted to plastids and mitochondria. Re-evaluation of the intracellular localization of chaperonins by electron microscopy, using two different anti-chaperonin antisera, revealed additionally their presence in the cytosol of oat primary leaf and coleoptile cells. The distribution of cpn 60 is not influenced by heat or light treatments.

A stromal protein factor maintains the solubility and insertion competence of an imported thylakoid membrane protein

The light-harvesting chlorophyll a/b protein (LHCP) is an approximately 25,000-D thylakoid membrane protein. LHCP is synthesized in the cytosol as a precursor and must translocate across the chloroplast envelope before becoming integrally associated with the thylakoid bilayer. Previous studies demonstrated that imported LHCP traverses the chloroplast stroma as a soluble intermediate before thylakoid insertion. Here, examination of this intermediate revealed that it is a stable, discrete approximately 120,000-D species and thus either an LHCP oligomer or a complex with another component. In vitro-synthesized LHCP can be converted to a similar form by incubation with a stromal extract. The stromal component responsible for this conversion is proteinaceous as evidenced by its inactivation by heat, protease, and NEM. Furthermore, the conversion activity coelutes from a gel filtration column with a stromal protein factor(s) previously shown to be necessary for LHCP integration into isolated thylakoids. Conversion of LHCP to the 120-kD form prevents aggregation and maintains its competence for thylakoid insertion. However, conversion to this form is apparently not sufficient for membrane insertion because the isolated 120-kD LHCP still requires stroma to complete the integration process. This suggests a need for at least one more stroma-mediated reaction. Our results explain how a hydrophobic thylakoid protein remains soluble as it traverses the aqueous stroma. Moreover, they describe in part the function of the stromal requirement for insertion into the thylakoid membrane.

Identification of a groES-like chaperonin in mitochondria that facilitates protein folding

Mitochondria contain a polypeptide that is functionally equivalent to Escherichia coli chaperonin 10 (cpn10; also known as groES). This mitochondrial cpn10 has been identified in beef and rat liver and is able to replace bacterial cpn10 in the chaperonin-dependent reconstitution of chemically denatured ribulose-1,5-bisphosphate carboxylase. Thus, like the bacterial homologue, mitochondrial cpn10 facilitates a K(+)- and Mg.ATP-dependent discharge of unfolded (or partially folded) ribulose bisphosphate carboxylase from bacterial chaperonin 60 (cpn60; also known as groEL). Instrumental to its identification, mitochondrial cpn10 and bacterial cpn60 form a stable complex in the presence of Mg.ATP. Bacterial and mitochondrial cpn10 compete for a common saturable site on bacterial cpn60. As a result of complex formation, with either mitochondrial or bacterial cpn10, the "uncoupled ATPase" activity of bacterial cpn60 is virtually abolished. The most likely candidate for mitochondrial cpn10 is an approximately 45-kDa oligomer composed of approximately 9-kDa subunits. We propose that, like the protein-folding machinery of prokaryotes, mitochondrial cpn60 requires a cochaperonin for full biological function.

In-vivo and in-vitro synthesis of photosynthetic fructose-1,6-bisphosphatase from pea (Pisum sativum L.)

Etiolated pea (Pisum sativum L. cv. Lincoln) seedlings do not show any capability for the biosynthesis of chloroplast fructose-1,6-bisphosphatase (FBPase), but the rate of biosynthesis of the increases with the pre-illumination time. This light-induced FBPase synthesis appears to be regulated at the transcriptional level, the response of young leaves being greater than that of mature ones. In-vivo labelling experiments demonstrated by immunoprecipitation, followed by sodium dodecyl sulfate electrophoresis and fluorography, the presence of a 49-kilodalton (kDa) band which corresponds to the mature FBPase subunit. In-vitro translation experiments with a wheat-germ synthesizing system and polyadenylated mRNA isolated from illuminated young pea seedlings have demonstrated the appearance of a 59-kDa labelled band corresponding to the precursor of the FBPase basic subunit. When intact pea chloroplasts were added to the above in-vitro incubation mixture, a labelled 49-kDa subunit similar to that of the in-vivo experiments appeared in the organelle under illumination. From these results we can conclude that a 10-kDa transit peptide bound to the translated pea FBPase subunit exists in the cytosol; this transit peptide is lost during passage through the chloroplast envelope, leaving the mature subunit inside the organelle.

Function of the maize mitochondrial chaperonin hsp60: specific association between hsp60 and newly synthesized F1-ATPase alpha subunits

Mitochondria contain a protein, hsp60, that is induced by heat shock and has been shown to function as a chaperonin in the assembly of mitochondrial enzyme complexes composed of proteins encoded by nuclear genes and imported from the cytosol. To determine whether products of mitochondrial genes are also assembled through an interaction with hsp60, we looked for association between hsp60 and proteins synthesized by isolated mitochondria. We have determined by electrophoretic, centrifugal, and immunological assays that at least two of those proteins become physically associated with hsp60. In mitochondrial matrix extracts, this association could be disrupted by the addition of Mg-ATP. One of the proteins that formed a stable association with hsp60 was the alpha subunit of the multicomponent complex F1-ATPase. We have not identified the other protein. These results indicate that hsp60 can function in the folding and assembly of mitochondrial proteins encoded by both mitochondrial and nuclear genes.

Function of the maize mitochondrial chaperonin hsp60: specific association between hsp60 and newly synthesized F1-ATPase alpha subunits

Mitochondria contain a protein, hsp60, that is induced by heat shock and has been shown to function as a chaperonin in the assembly of mitochondrial enzyme complexes composed of proteins encoded by nuclear genes and imported from the cytosol. To determine whether products of mitochondrial genes are also assembled through an interaction with hsp60, we looked for association between hsp60 and proteins synthesized by isolated mitochondria. We have determined by electrophoretic, centrifugal, and immunological assays that at least two of those proteins become physically associated with hsp60. In mitochondrial matrix extracts, this association could be disrupted by the addition of Mg-ATP. One of the proteins that formed a stable association with hsp60 was the alpha subunit of the multicomponent complex F1-ATPase. We have not identified the other protein. These results indicate that hsp60 can function in the folding and assembly of mitochondrial proteins encoded by both mitochondrial and nuclear genes.

Photoaffinity labeling of ribulose-bisphosphate carboxylase/oxygenase with 8-azidoadenosine 5'-triphosphate

Photoaffinity labeling with [(32)P] 8-azidoadenosine 5'-triphosphate (8-N3ATP) was used to identify putative binding sites on tobacco (Nicotiana tabacum L. and N. rustica L.) leaf ribulose-1,5-bisphosphate carboxylase/oxygenase (RuBPCase, EC 4.1.1.39). Incorporation of (32)P was observed in polypeptides corresponding to both RuBPCase subunits when desalted leaf and chloroplast extracts, and purified RuBPCase were irradiated with ultraviolet light in the presence of [(32)P] 8-N3ATP. (32)P-labeling was dependent upon ultraviolet irradiation and occurred with [(32)P] 8-N3ATP labeled in the α-position, indicating covalent incorporation of the photoprobe. Both [(32)P] 8-N3ATP and [(32)P] 8-N3GTP were incorporated to a similar extent into the 53-kilodalton (kDa) "large" subunit (LSu), but incorporation of [(32)P] 8-N3GTP into the 14-kDa "small" subunit (SSu) of RuBPCase was <5% of that measured with [(32)P] 8-N3ATP. Distinct binding sites for 8-N3ATP on the two subunits were indicated by different apparent K D values, 3 and 18 μM for the SSu and LSu, respectively, and differences in the response of photoaffinity labeling to Mg(2+), anions and enzyme activation. Active-site-directed compounds, including the non-gaseous substrate ribulose 1,5-bisphosphate, the reaction intermediate analog 2-carboxyarabinitol-1,5-bisphosphate and several phosphorylated effectors afforded protection to the LSu site against photoincorporation but provided almost no protection to the SSu. These results indicate that 8-N3ATP binds to the active-site region of the LSu and a distinct site on the SSu of RuBPCase. Experiments conducted with intact pea (Pisum sativum L.) and tobacco chloroplasts showed that the SSu was not photolabeled with [(32)P] 8-N3ATP in organello or in undesalted chloroplast lysates but was photolabeled when lysates were ultrafiltered or desalted. These results indicate that 8-N3ATP binds to a site on the SSu that has physiological significance.

Several proteins imported into chloroplasts form stable complexes with the GroEL-related chloroplast molecular chaperone

Nine different proteins were imported into isolated pea chloroplasts in vitro. For seven of these [the large and small subunits of ribulose-1,5-bisphosphate carboxylase/oxygenase (Rubisco), beta-subunit of ATP synthase, glutamine synthetase, the light-harvesting chlorophyll a/b binding protein, chloramphenicol acetyltransferase, and pre-beta-lactamase], a fraction was found to migrate as a stable high-molecular-weight complex during nondenaturing gel electrophoresis. This complex contained the mature forms of the imported proteins and the groEL-related chloroplast chaperonin 60 (previously known as Rubisco subunit binding protein). Thus, the stable association of imported proteins with this molecular chaperone is widespread and not necessarily restricted to Rubisco subunits or to chloroplast proteins. With two of the imported proteins (ferredoxin and superoxide dismutase), such complexes were not observed. It seems likely that, in addition to its proposed role in assembly of Rubisco, the chloroplast chaperonin 60 is involved in the assembly or folding of a wide range of proteins in chloroplasts.

A point mutation in the gene for the large subunit of ribulose 1,5-bisphosphate carboxylase/oxygenase affects holoenzyme assembly in Nicotiana tabacum

In photosynthetic eukaryotes, the enzyme ribulose-1,5-bisphosphate carboxylase/oxygenase (Rubisco) is composed of eight large and eight small subunits. Chloroplast-coded large subunits are found in association with chaperonins (binding proteins) of 60-61 kd to form a high mol. wt pre-assembly complex (B-complex). We have isolated a heterotrophic, maternally-inherited mutant from Nicotiana tabacum var. Xanthi which accumulates the B-complex but contains no Rubisco holoenzyme. The B-complex of the mutant dissociates in the presence of ATP, as does that of the wild-type. Processing of the nuclear-coded small subunit takes place in the mutant and neither large nor small subunits accumulate. The large subunit gene from mutant and wild-type plants was cloned and sequenced. A single nucleotide difference was found between them predicting an amino acid change of serine to phenylalanine at position 112 in the mutant. Based on the resolved structure of N.tabacum Rubisco, it is argued that the alteration at position 112 prevents holoenzyme assembly by interfering with large subunit assembly.

Delayed Osmotic Effect on in Vitro Assembly of RuBisCO : Relationship to Large Subunit-Binding Protein Complex Dissociation

Higher plant ribulose-1,5-bisphosphate carboxylase/oxygenase (RuBisCO) cannot reassociate after dissociation, and its subunits do not assemble into active RuBisCO when synthesized in Escherichia coli. Newly synthesized subunits of RuBisCO are associated with a high molecular weight binding protein complex in pea chloroplasts. The immediate donor for large subunits which assemble into RuBisCO is a low molecular weight complex which may be derived from the high molecular weight binding protein complex. When the high molecular weight binding protein complex is diluted, it tends to dissociate, forming low molecular weight complexes. When the large subunit-binding protein complexes were examined after in organello protein synthesis, it was found that the low molecular weight complexes were more abundant when protein synthesis was carried out under hypotonic conditions. This increase in the assembly competent population of low molecular weight large subunit complexes can account for the increased amount of in vitro RuBisCO assembly which occurs under these conditions. The data indicate that the assembly of large subunits into RuBisCO is a function of the aggregation state of the large subunit binding protein complex during protein synthesis. This implies that the binding protein exerts its effects during or shortly after large subunit synthesis.

Assembly of Rubisco from native subunits

Large subunits of ribulosebisphosphate carboxylase/oxygenase (Rubisco) (3-phospho-D-glycerate carboxy-lyase (dimerizing), EC 4.1.1.39) from prokaryotic sources can assemble into intact enzyme either in vitro or in Escherichia coli cells. Large subunits of higher plant Rubisco do not assemble into Rubisco in E. coli cells, nor is it possible to reconstitute higher plant Rubisco from its dissociated subunits in vitro. This behavior represents an obstacle to any practical attempts at engineering the higher plant enzyme, and it suggests that the in vivo assembly mechanism of higher plant Rubisco must be more complex than is commonly expected for oligomeric proteins of organelles. In pea chloroplasts, a binding protein interacts with newly synthesized large subunits, in quantities expected for an intermediate in the assembly process, as judged by Western blotting. Radiotracer-labeled large subunits which interact with this binding protein can be shown to assemble into Rubisco in reactions which lead to changes in the aggregation state of the binding protein. Antibody to this binding protein specifically inhibits the assembly of these subunits into Rubisco. Rubisco synthesis appears to be subject to many types of control: gene dosage, transcription rate, selective translation of message, post-translational degradation and threshold concentration effects have been observed in various organisms' synthesis of Rubisco. The biochemical mechanisms underlying most of these effects have not been elucidated. The post-translational assembly mechanism in particular appears to require further study.

Localization of a 64-kDa phosphoprotein in the lumen between the outer and inner envelopes of pea chloroplasts

The identification and localization of a marker protein for the intermembrane space between the outer and inner chloroplast envelopes is described. This 64-kDa protein is very rapidly labeled by [gamma-32P]ATP at very low (30 nM) ATP concentrations and the phosphoryl group exhibits a high turnover rate. It was possible to establish the presence of the 64-kDa protein in this plastid compartment by using different chloroplast envelope separation and isolation techniques. In addition comparison of labeling kinetics by intact and hypotonically lysed pea chloroplasts support the localization of the 64-kDa protein in the intermembrane space. The 64-kDa protein was present and could be labeled in mixed envelope membranes isolated from hypotonically lysed plastids. Mixed envelope membranes incorporated high amounts of 32P from [gamma-32P]ATP into the 64-kDa protein, whereas separated outer and inner envelope membranes did not show significant phosphorylation of this protein. Water/Triton X-114 phase partitioning demonstrated that the 64-kDa protein is a hydrophilic polypeptide. These findings suggest that the 64-kDa protein is a soluble protein trapped in the space between the inner and outer envelope membranes. After sonication of mixed envelope membranes, the 64-kDa protein was no longer present in the membrane fraction, but could be found in the supernatant after a 110,000 x g centrifugation.

Molecular and cellular regulation of autotrophic carbon dioxide fixation in microorganisms

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Homologous plant and bacterial proteins chaperone oligomeric protein assembly

An abundant chloroplast protein is implicated in the assembly of the oligomeric enzyme ribulose bisphosphate carboxylase-oxygenase, which catalyses photosynthetic CO2-fixation in higher plants. The product of the Escherichia coli groEL gene is essential for cell viability and is required for the assembly of bacteriophage capsids. Sequencing of the groEL gene and the complementary cDNA encoding the chloroplast protein has revealed that these proteins are evolutionary homologues which we term 'chaperonins'. Chaperonins comprise a class of molecular chaperones that are found in chloroplasts, mitochondria and prokaryotes. Assisted post-translational assembly of oligomeric protein structures is emerging as a general cellular phenomenon.

The Rubisco subunit binding protein

Chloroplasts contain an abundant soluble protein that binds non-covalently newly synthesized large and small subunits of the enzyme ribulose bisphosphate carboxylase-oxygenase. This binding protein has been purified from Pisum sativum and Hordeum vulgare in the form of a dodecamer consisting of equal amounts of two types of subunit. These subunits are synthesized as higher molecular mass precursors by cytoplasmic ribosomes before import into the chloroplast. Antibodies raised against the purified binding protein from Pisum sativum detect polypeptides not only in extracts of plastids from several plant species but also in cell extracts of several bacterial species. The oligomeric binding protein dissociates reversibly into monomeric subunits in the presence of 1-5 mmol/liter MgATP. For one type of subunit the cDNA sequence has been isolated and determined and reveals homology with certain bacterial proteins.These observations are discussed in relation to the idea that the binding protein is an example of a general class of proteins termed "molecular chaperones" which are required for the correct assembly of certain oligomeric proteins such as the carboxylase from their subunits.

Stability and Dissociation of the Large Subunit RuBisCO Binding Protein Complex in Vitro and in Organello

We are studying the stability of the binding protein which associates with newly synthesized large subunits of ribulose bisphosphate carboxylase. In chloroplast extracts, it has been shown that a dodecameric complex of the large subunit binding protein dissociates extensively into binding protein monomers and 7S (117 kilodaltons) large subunit-containing complexes in the presence of ATP. The concentrations of ATP which bring this about are quite low, prompting some investigators to suggest that the dodecameric complex might not exist in vivo. We have found, however, that in concentrated chloroplast extracts, at protein concentrations which are closer to those which occur in organello, the dissociation of the binding protein complex by ATP is much less extensive. For this reason, we have tested the stability of the binding protein in organello, by illuminating chloroplasts followed by lysis and polyacrylamide gel electrophoresis of the extracts. Radioactive large subunits associated with the dodecameric binding protein dissociated extensively in the light. The results are consistent with the idea that the high molecular weight form of the binding protein can function as a reservoir of large subunits which can be tapped in vivo, in a reaction dependent on light and ATP.

Protein synthesis by isolated chloroplasts

Isolated chloroplasts show substantial rates of protein synthesis when illuminated. This 'in organello' protein synthesis system has been advantageously utilised to elucidate the coding capacity of chloroplast and the regulation of chloroplast genes. The system is also being used recently to transcribe and translate homologous and heterologous templates. In this mini-review, we attempt to critically ecaluate the available literature and present the current and the prospective lines of research.

Incorporation of Large Subunits into Ribulose Bisphosphate Carboxylase in Chloroplast Extracts : Influence of Added Small Subunits and of Conditions during Synthesis

The incorporation of newly synthesized large subunits into ribulose bisphosphate carboxylase/oxygenase (RuBisCO) in pea chloroplast extracts occurs at the expense of intermediate forms of the large subunit which are complexed with a binding protein. Most subunits of this binding protein are found in dodecameric complexes in chloroplast extracts. Addition of small subunits to these extracts results in approximately 40 to 60% increased incorporation of newly made large subunits into RuBisCO at low or zero concentrations of ATP, but is without significant effect at high concentrations of ATP, a condition in which the dodecameric binding protein complex is dissociated into subunits. Overall, these data support the assumption that the incorporation of large subunits into RuBisCO in chloroplast extracts reflects de novo assembly rather than ;mere' exchange of subunits. The in vitro assembly of large subunits into RuBisCO is a function of the conditions under which the large subunits are synthesized in organello. When the large subunits are made in chloroplasts suspended in 188 millimolar sorbitol, they are approximately 2- to 3-fold better able to assemble into RuBisCO when subsequently incubated in vitro than when they are synthesized in chloroplasts suspended in 375 millimolar sorbitol. This observation indicates that mere synthesis of large subunits is not sufficient to confer maximal assembly competence on large subunits.

Co-expression of both the maize large and wheat small subunit genes of ribulose-bisphosphate carboxylase in Escherichia coli

A cDNA clone for the precursor form of the small subunit of wheat ribulose-bisphosphate carboxylase has been modified to allow the expression in Escherichia coli of a mature form of small subunit that lacks the transit peptide. Synthesis of the protein is controlled by a lac promoter, and translation is initiated from a lacZ ribosome binding site, giving rise to a small subunit with several beta-galactosidase amino acids fused to its N-terminus. A plasmid has been constructed that enables both wheat small subunits and maize large subunits to be synthesized in the bacterial cell, but using different promoters to allow independent expression of the rbcS and rbcL genes. When the small subunit is synthesized in the absence of the large subunit, it is found in the soluble fraction but the polypeptide is unstable and has a half-life of less than 15 min. Its size on sucrose gradients indicates a monomeric or dimeric form. When large subunit synthesis is induced in cells containing the small subunit, both subunits are found predominantly in the insoluble fraction and are fully stable for more than 120 min, suggesting that aggregation of the subunits may occur. The two subunits do not assemble together to form an active holoenzyme in vivo, even when nascent large subunits ware synthesized in a pool of mature small subunits. This indicates that other factors may be required to mediate the assembly of the higher plant enzyme.

Dissociation of the ribulosebisphosphate-carboxylase large-subunit binding protein into dissimilar subunits

The ribulosebisphosphate-carboxylase large-subunit binding protein from Pisum sativum chloroplasts is an oligomer of two types of subunit with the composition alpha 6 beta 6. These two subunits are immunologically distinct, show different partial protease digestion patterns and have different amino-terminal sequences. Leaves of Hordeum vulgare also contain an oligomeric binding protein composed of equal amounts of two types of subunit. Treatment of either P. sativum stromal extracts or purified binding protein with ATP and Mg2+ ions causes the dissociation of the oligomeric form of the binding protein to the monomeric subunits. This effect is highly specific for ATP since CTP, UTP, GTP, ADP, AMP, cyclic AMP, NADPH and pyrophosphate do not cause dissociation.

Inhibition of ribulose bisphosphate carboxylase assembly by antibody to a binding protein

We have developed an assay to monitor in vitro the posttranslational assembly of the chloroplast protein, ribulose-1,5-bisphosphate carboxylase/oxygenase (RuBisCO). Most of the newly synthesized 55-kD catalytic ("large") subunits of this enzyme occur in a 29S complex together with 60- and 61-kD "binding" proteins. When the 29S complex is incubated with ATP and MgCl2 it dissociates into subunits, and the formerly bound large subunits now sediment at 7S (still faster than expected for a monomer). Upon incubation at 24 degrees C, these large subunits assemble into RuBisCO. The minority of newly made large subunits which are not bound to the 29S complex also sediment at 7S. When endogenous ATP was removed by addition of hexokinase and glucose, the dissociation of the 29S complex was inhibited. Nevertheless, the 7S large subunits assembled into RuBisCO, and did so to a greater extent than in controls retaining endogenous ATP. Thus the 7S large subunits are also assembly competent, at least when ATP is removed. Apparently, in chloroplast extracts, ATP can have a dual effect on the assembly of RuBisCO: on the one hand, even at low concentrations it can inhibit incorporation of 7S large subunits RuBisCO; on the other hand, at higher concentrations it can lead to substantial buildup of the 7S large subunit pool by causing dissociation of the 29S complex, and stimulate overall assembly. At both high and zero concentrations of ATP, however, antibody to the binding protein inhibited the assembly of endogenous large subunits into RuBisCO. Thus it appears that all assembly-competent large subunits are associated with the binding protein, either in the 7S complex or in the 29S complex. The involvement of the binding protein in RuBisCO assembly may represent the first example of non-autonomous protein assembly in higher plants and may pose problems for the genetic engineering of RuBisCO from these organisms.

Optimization of protein synthesis in isolated higher plant chloroplasts. Identification of paused translation intermediates

Protein synthesis in isolated, intact pea chloroplasts was optimized and compared to translation within chloroplasts in vivo. Many polypeptides labeled with [35S]methionine in isolated intact chloroplasts did not comigrate with polypeptides which were labeled within chloroplasts in vivo. Antibodies to the large subunit of ribulose-1,5-bisphosphate carboxylase-oxygenase (EC 4.1.1.39) immunoprecipitated [35S]-labeled large subunit plus several lower-molecular-mass translation products of isolated chloroplasts. The lower-molecular-mass soluble translation products synthesized in pulse-labeled chloroplasts were converted into full-length large-subunit polypeptides during a subsequent chase period. This result suggests that many of the polypeptides observed in pulse-labeled chloroplasts are incomplete translation products which are the result of ribosome pausing at discrete points along chloroplast mRNAs. The pulse-chase technique was used to follow synthesis of the 34.5-kDa precursor of the psb A gene product and its processing to the mature 32-kDa polypeptide in isolated chloroplasts. Chloroplast translation profiles obtained using the pulse-chase assay were very similar to translation profiles obtained in vivo thus extending the utility of protein synthesis in isolated chloroplasts.