Identification of a 350-kDa ClpP protease complex with 10 different Clp isoforms in chloroplasts of Arabidopsis thaliana

A 350-kDa ClpP protease complex with 10 different subunits was identified in chloroplast of Arabidopsis thaliana, using Blue-Native gel electrophoresis, followed by matrix-assisted laser desorption ionization time-of-flight and nano-electrospray tandem mass spectrometry. The complex was copurified with the thylakoid membranes, and all identified Clp subunits show chloroplast targeting signals, supporting that this complex is indeed localized in the chloroplast. The complex contains chloroplast-encoded pClpP and six nuclear-encoded proteins nCpP1-6, as well as two unassigned Clp homologues (nClpP7, nClpP8). An additional Clp protein was identified in this complex; it does not belong to any of the known Clp genes families and is here assigned ClpS1. Expression and accumulation of several of these Clp proteins have never been shown earlier. Sequence and phylogenetic tree analysis suggests that nClpP5, nClpP2, and nClpP8 are not catalytically active and form a new group of Clp higher plant proteins, orthologous to the cyanobacterial ClpR protein, and are renamed ClpR1, -2, and -3, respectively. We speculate that ClpR1, -2, and -3 are part of the heptameric rings, whereas ClpS1 is a regulatory subunit positioned at the axial opening of the ClpP/R core. Several truncations and errors in intron and exon prediction of the annotated Clp genes were corrected using mass spectrometry data and by matching genomic sequences with cDNA sequences. This strategy will be widely applicable for the much needed verification of protein prediction from genomic sequence. The extreme complexity of the chloroplast Clp complex is discussed.     

The chloroplast protease subunit ClpP4 is a substrate of the E3 ligase AtCHIP and plays an important role in chloroplast function

Animal CHIP proteins are chaperone-dependent E3 ubiquitin ligases that physically interact with Hsp70, Hsp90 and proteasome, promoting degradation of a selective group of non-native or damaged proteins in animal cells. The plant CHIP-like protein, AtCHIP, also plays important roles in protein turnover metabolism. AtCHIP interacts with a proteolytic subunit, ClpP4, of the chloroplast Clp protease in vivo, and ubiquitylates ClpP4 in vitro. The steady-state level of ClpP4 is reduced in AtCHIP-overexpressing plants under high-intensity light conditions, suggesting that AtCHIP targets ClpP4 for degradation and thereby regulates the Clp proteolytic activity in chloroplasts under certain stress conditions. Overexpression of ClpP4 in Arabidopsis leads to chlorotic phenotypes in transgenic plants, and chloroplast structures in the chlorotic tissues of ClpP4-overexpressing plants are abnormal and largely devoid of thylakoid membranes, suggesting that ClpP4 plays a critical role in chloroplast structure and function. As AtCHIP is a cytosolic protein that has been shown to play an important role in regulating an essential chloroplast protease, this research provides new insights into the regulatory networks controlling protein turnover catabolism in chloroplasts.     

Structural and functional insights into the chloroplast ATP-dependent Clp protease in Arabidopsis

In contrast with the model Escherichia coli Clp protease, the ATP-dependent Clp protease in higher plants has a remarkably diverse proteolytic core consisting of multiple ClpP and ClpR paralogs, presumably arranged within a dual heptameric ring structure. Using antisense lines for the nucleus-encoded ClpP subunit, ClpP6, we show that the Arabidopsis thaliana Clp protease is vital for chloroplast development and function. Repression of ClpP6 produced a proportional decrease in the Clp proteolytic core, causing a chlorotic phenotype in young leaves that lessened upon maturity. Structural analysis of the proteolytic core revealed two distinct subcomplexes that likely correspond to single heptameric rings, one containing the ClpP1 and ClpR1-4 proteins, the other containing ClpP3-6. Proteomic analysis revealed several stromal proteins more abundant in clpP6 antisense lines, suggesting that some are substrates for the Clp protease. A proteolytic assay developed for intact chloroplasts identified potential substrates for the stromal Clp protease in higher plants, most of which were more abundant in young Arabidopsis leaves, consistent with the severity of the chlorotic phenotype observed in the clpP6 antisense lines. The identified substrates all function in more general housekeeping roles such as plastid protein synthesis, folding, and quality control, rather than in metabolic activities such as photosynthesis.     

Distinctive types of ATP-dependent Clp proteases in cyanobacteria

Cyanobacteria are the only prokaryotes that perform oxygenic photosynthesis and are thought to be ancestors to plant chloroplasts. Like chloroplasts, cyanobacteria possess a diverse array of proteolytic enzymes, with one of the most prominent being the ATP-dependent Ser-type Clp protease. The model Clp protease in Escherichia coli consists of a single ClpP proteolytic core flanked on one or both ends by a HSP100 chaperone partner. In comparison, cyanobacteria have multiple ClpP paralogs plus a ClpP variant (ClpR), which lacks the catalytic triad typical of Ser-type proteases. In this study, we reveal that two distinct soluble Clp proteases exist in the unicellular cyanobacterium Synechococcus elongatus. Each protease consists of a unique proteolytic core comprised of two separate Clp subunits, one with ClpP1 and ClpP2, the other with ClpP3 and ClpR. Each core also associates with a particular HSP100 chaperone partner, ClpC in the case of the ClpP3/R core, and ClpX for the ClpP1/P2 core. The two adaptor proteins, ClpS1 and ClpS2 also interact with the ClpC chaperone protein, likely increasing the range of protein substrates targeted by the Clp protease in cyanobacteria. We also reveal the possible existence of a third Clp protease in Synechococcus, one which associates with the internal membrane network. Altogether, we show that presence of several distinctive Clp proteases in cyanobacteria, a feature which contrasts from that in most other organisms.     

Identification of clp genes expressed in senescing Arabidopsis leaves.

Clp protease is a highly selective protease in E. coli, which consists of two types of subunits, the regulatory subunit with ATPase activity, ClpA, and the catalytic subunit, ClpP. In order to examine the possible association of plant Clp protease with the degradation of protein in senescing chloroplasts, we isolated a cDNA clone for ClpC which is a plant homologue of ClpA from Arabidopsis thaliana in addition to ERD1 which we had isolated earlier [Kiyosue et al. (1993) Biochem. Biophys. Res. Commun. 196: 1214]. We also isolated a clone for the plastidic gene, clpP (pclpP) and cDNA clones for putative nuclear clpP genes (nclpP1-6). We analyzed the expression of these clp genes in Arabidopsis leaves after various dark periods and during natural senescence. The expression of erd1 was increased by dark-induced and by natural senescence, as reported earlier [Nakashima et al. (1997) Plant J. 12: 851], while that of AtclpC was decreased. Two catalytic subunits nclpPs (nclpP3 and nclpP5) showed high expression in naturally senescing leaves, but the expression of pclpP and the other nclpPs was not changed. Immunoblot analysis of chloroplast protein and in vitro import analysis demonstrated that both nucleus-encoded regulatory subunits as well as nClpP5 were localized in the chloroplast stroma. These observations suggest that chloroplast Clp protease is composed of very complicated combinations of subunits, and that ERD1, nClpP5 and pClpP have a role in the concerted degradation of protein in senescing chloroplasts.     

ATP-dependent association between subunits of Clp protease in pea chloroplasts

The chloroplast ATP-dependent Clp protease (EC 3.4.21.92) is composed of the proteolytic subunit ClpP and the regulatory ATPase, ClpC. Although both subunits are found in the stroma, the interaction between the two is dynamic. When immunoprecipitation with antibodies against ClpC was performed on stroma from dark-adapted pea (Pisum sativum L. cv. Alaska) chloroplasts, ClpC but not ClpP was precipitated. However, when stroma was supplemented with ATP, both ClpC and ClpP were precipitated. Co-immunoprecipitation was even more efficient in the presence of ATP-gamma-S, suggesting that the association between regulatory and proteolytic subunits is dependent on binding of ATP to ClpC, but not its hydrolysis. To further test this association, stroma was fractionated by column chromatography, and the presence of Clp subunits in the different fractions was monitored immunologically. When stroma depleted of ATP was fractionated on an ion-exchange column, ClpP and ClpC migrated separately, whereas in the presence of ATP-gamma-S both subunits co-migrated. Similar results were observed in size-exclusion chromatography. To further characterize the precipitated enzyme, its proteolytic activity was assayed by testing its ability to degrade beta-casein. No degradation was observed in the absence of ATP, and degradation was inhibited in the presence of phenylmethylsulfonyl fluoride, consistent with Clp being an ATP-dependent serine protease. The activity of the isolated enzyme was further tested using chimeric OE33 as a model substrate. This protein was also degraded in an ATP-dependent manner, supporting the suggested role of Clp protease as a major housekeeping protease in the stroma.     

Assembly of the chloroplast ATP-dependent Clp protease in Arabidopsis is regulated by the ClpT accessory proteins

The ATP-dependent caseinolytic protease (Clp) is an essential housekeeping enzyme in plant chloroplasts. It is by far the most complex of all known Clp proteases, with a proteolytic core consisting of multiple catalytic ClpP and noncatalytic ClpR subunits. It also includes a unique form of Clp protein of unknown function designated ClpT, two of which exist in the model species Arabidopsis thaliana. Inactivation of ClpT1 or ClpT2 significantly reduces the amount of Clp proteolytic core, whereas loss of both proves seedling lethal under autotrophic conditions. During assembly of the Clp proteolytic core, ClpT1 first binds to the P-ring (consisting of ClpP3-6 subunits) followed by ClpT2, and only then does the P-ring combine with the R-ring (ClpP1, ClpR1-4 subunits). Most of the ClpT proteins in chloroplasts exist in vivo as homodimers, which then apparently monomerize prior to association with the P-ring. Despite their relative abundance, however, the availability of both ClpT proteins is rate limiting for the core assembly, with the addition of recombinant ClpT1 and ClpT2 increasing core content up to fourfold. Overall, ClpT appears to regulate the assembly of the chloroplast Clp protease, revealing a new and sophisticated control mechanism on the activity of this vital protease in plants.     

Substrate delivery by the AAA+ ClpX and ClpC1 unfoldases activates the mycobacterial ClpP1P2 peptidase

Mycobacterial Clp‐family proteases function via collaboration of the heteromeric ClpP1P2 peptidase with a AAA+ partner, ClpX or ClpC1. These enzymes are essential for M. tuberculosis viability and are validated antibacterial drug targets, but the requirements for assembly and regulation of functional proteolytic complexes are poorly understood. Here, we report the reconstitution of protein degradation by mycobacterial Clp proteases in vitro and describe novel features of these enzymes that distinguish them from orthologues in other bacteria. Both ClpX and ClpC1 catalyse ATP‐dependent unfolding and degradation of native protein substrates in conjunction with ClpP1P2, but neither mediates protein degradation with just ClpP1 or ClpP2. ClpP1P2 alone has negligible peptidase activity, but is strongly stimulated by translocation of protein substrates into ClpP1P2 by either AAA+ partner. Interestingly, our results support a model in which both binding of a AAA+ partner and protein‐substrate delivery are required to stabilize active ClpP1P2. Our model has implications for therapeutically targeting ClpP1P2 in dormant M. tuberculosis, and our reconstituted systems should facilitate identification of novel Clp protease inhibitors and activators.     

Phytoene synthase from tomato (Lycopersicon esculentum) chloroplasts – partial purification and biochemical properties

 Phytoene synthase activity in tomato chloroplasts is membrane-associated, requiring treatment with high ionic strength buffer or mild non-ionic detergent for solubilisation. Using a combination of ammonium sulphate precipitation, cation and anion exchange, dye-ligand and hydrophobic interaction chromatography, phytoene synthase has been purified 600-fold from tomato (Lycopersicon esculentum Mill.) chloroplasts. The native molecular mass of the enzyme was 43 kDa, with an isoelectric point of 4.6. Although phytoene synthase was functional in a monomeric state, under optimal native conditions it was associated with a large (at least 200 kDa) protein complex which contained other terpenoid enzymes such as isopentenyl diphosphate isomerase and geranylgeranyl diphosphate (GGPP) synthase. Both Mn²⁺ and ATP, in combination, were essential for catalytic activity; their effect was stochiometric from 0.5 to 2 mM, with K _m values for Mn²⁺, ATP and the substrate GGPP of 0.4 mM, 2.0 mM and 5 μM, respectively. The detergents Tween 60 and Triton X-100 (0.1 w/v) stimulated (5-fold) enzyme activity, but lipids (crude chloroplast lipids and phospholipids) had no such effect and could not compensate for the absence of detergent. A number of metabolites with possible regulatory effects were investigated, including β-carotene, which reduced enzyme activity in vitro some 2-fold. A comparison of phytoene synthase activity from partially purified chloroplast and chromoplast preparations indicated biochemical differences. Received: 20 January 2000 / Accepted: 16 February 2000     

The Mycobacterium tuberculosis ClpP1P2 Protease Interacts Asymmetrically with Its ATPase Partners ClpX and ClpC1

Clp chaperone-proteases are cylindrical complexes built from ATP-dependent chaperone rings that stack onto a proteolytic ClpP double-ring core to carry out substrate protein degradation. Interaction of the ClpP particle with the chaperone is mediated by an N-terminal loop and a hydrophobic surface patch on the ClpP ring surface. In contrast to E. coli, Mycobacterium tuberculosis harbors not only one but two ClpP protease subunits, ClpP1 and ClpP2, and a homo-heptameric ring of each assembles to form the ClpP1P2 double-ring core. Consequently, this hetero double-ring presents two different potential binding surfaces for the interaction with the chaperones ClpX and ClpC1. To investigate whether ClpX or ClpC1 might preferentially interact with one or the other double-ring face, we mutated the hydrophobic chaperone-interaction patch on either ClpP1 or ClpP2, generating ClpP1P2 particles that are defective in one of the two binding patches and thereby in their ability to interact with their chaperone partners. Using chaperone-mediated degradation of ssrA-tagged model substrates, we show that both Mycobacterium tuberculosis Clp chaperones require the intact interaction face of ClpP2 to support degradation, resulting in an asymmetric complex where chaperones only bind to the ClpP2 side of the proteolytic core. This sets the Clp proteases of Mycobacterium tuberculosis, and probably other Actinobacteria, apart from the well-studied E. coli system, where chaperones bind to both sides of the protease core, and it frees the ClpP1 interaction interface for putative new binding partners.     

A ClpP protein model as tuberculosis target for screening marine compounds

ATP-dependent Clp protease (ClpP) is a core unit of a major bacterial protease complex employing as a new attractive drug target for that isolates, which are resistant to antibiotics. Mycobacterium tuberculosis, a gram-positive bacterium, is one of the major causes of hospital acquired infections. ClpP in Mycobacterium tuberculosis is usually tightly regulated and strictly requires a member of the family of Clp-ATPase and often further accessory proteins for proteolytic activation. Inhibition of ClpP eliminates these safeguards and start proteolytic degradation. Such uncontrolled proteolysis leads to inhibition of bacterial cell division and eventually cell death. In order to inhibit Clp protease, at first three dimensional structure model of ClpP in Mycobacterium tuberculosis was determined by comparative homology modeling program MODELLER based on crystal structure of the proteolytic component of the caseinolytic Clp protease (ClpP) from E. coli as a template protein and has 55%sequence identity with ClpP protein. The computed model's energy was minimized and validated using PROCHECK to obtain a stable model structure and is submitted in Protein Model Database (PMDB-ID: PM0075741). Stable model was further used for virtual screening against marine derived bioactive compound database through molecular docking studies using AutoDock 3.05. The docked complexes were validated and enumerated based on the AutoDock Scoring function to pick out the best marine inhibitors based on docked Energy. Thus from the entire 186 Marine compounds which were Docked, we got best 5 of them with optimal docked Energy (Ara-A: -14.31 kcal/mol, Dysinosin C: - 14.90kcal/mol, Nagelamide A: -20.49 kcal/mol, Strobilin: -8.02 kcal/mol, Manoalide: -8.81 kcal/mol). Further the five best-docked complexes were analyzed through Python Molecular Viewer software for their interaction studies. Thus from the Complex scoring and binding ability its deciphered that these Marine compounds could be promising inhibitors for ClpP as Drug target yet pharmacological studies have to confirm it.     

Immunochemical Studies on the Clp-protease in Chloroplasts: Evidence for the Formation of a CIpC/P Complex*

Chloroplasts contain a proteolytic system whose activity is ATP-dependent. The presence of genes encoding homologues of the ATP-dependent E. coli CIpA/P protease on the plastome and nuclear genome suggests that a similar protease is located in chloroplasts. Antibodies raised against a recombinant chloroplast-encoded proteolytic ClpP subunit detect this polypeptide in chloroplasts prepared from barley leaves or the eukaryotic algae Chlamydomonas reinhardtii and Euglena gracilis. Co-immunoprecipitation experiments using the anti-ClpP antibody and an antibody against the nuclear encoded regulatory CIpC component (a ClpA homologue) provide direct evidence for the existence of a CIpC/P complex in the chloroplast stroma. These results suggest that at least a part of the ATP-dependent proteolytic reactions in the chloroplast is catalyzed by an enzyme complex similar to the E. coli CIpA/P protease.     

Subunit stoichiometry, evolution, and functional implications of an asymmetric plant plastid ClpP/R protease complex in Arabidopsis

The caseinolytic protease (Clp) protease system has been expanded in plant plastids compared with its prokaryotic progenitors. The plastid Clp core protease consists of five different proteolytic ClpP proteins and four different noncatalytic ClpR proteins, with each present in one or more copies and organized in two heptameric rings. We determined the exact subunit composition and stoichiometry for the intact core and each ring. The chloroplast ClpP/R protease was affinity purified from clpr4 and clpp3 Arabidopsis thaliana null mutants complemented with C-terminal StrepII-tagged versions of CLPR4 and CLPP3, respectively. The subunit stoichiometry was determined by mass spectrometry-based absolute quantification using stable isotope-labeled proteotypic peptides generated from a synthetic gene. One heptameric ring contained ClpP3,4,5,6 in a 1:2:3:1 ratio. The other ring contained ClpP1 and ClpR1,2,3,4 in a 3:1:1:1:1 ratio, resulting in only three catalytic sites. These ClpP1/R1-4 proteins are most closely related to the two subunits of the cyanobacterial P3/R complex and the identical P:R ratio suggests conserved adaptation. Furthermore, the plant-specific C-terminal extensions of the ClpP/R subunits were not proteolytically removed upon assembly, suggesting a regulatory role in Clp chaperone interaction. These results will now allow testing ClpP/R structure-function relationships using rationale design. The quantification workflow we have designed is applicable to other protein complexes.     

The ATP-dependent Clp protease in chloroplasts of higher plants

The best-known proteases in plastids are those that belong to families common to eubacteria. One of the first identified was the ATP-dependent caseinolytic protease (Clp), whose structure and function have been well characterized in Escherichia coli . Plastid Clp proteins in higher plants are surprisingly numerous and diverse, with at least 16 distinct Clp proteins in the model plant Arabidopsis thaliana . Multiple paralogues exist for several of the different types of plastid Clp protein, with the most extreme being five for the proteolytic subunit ClpP. Both biochemical and genetic studies have recently begun to reveal the intricate structural interactions between the various Clp proteins, and their importance for chloroplast function and plant development. Much of the recent data suggests that the function of many of the Clp proteins probably affects more specific processes within chloroplasts, in addition to the more general 'housekeeping' role previously assumed.     

Purification and characterization of a glucokinase from young tomato (Lycopersicon esculentum L. Mill.) fruit

In order to clearly establish the properties of the enzymes responsible for hexose phosphorylation we have undertaken the separation and characterization of these enzymes present in tomato fruit (Martinez-Barajas and Randall 1996). This report describes the partial purification and characterization of glucokinase (EC. 2.7.1.1) from young green tomato fruit. The procedure yielded a 360-fold enrichment of glucokinase. Tomato fruit glucokinase is a monomer with a molecular mass of 53 kDa. Glucokinase activity was optimal between pH 7.5 and 8.5, preferred ATP as the phosphate donor (K _m = 0.223 mM) and exhibited low activity with GTP or UTP. The tomato fruit glucokinase showed highest affinity for glucose (K _m = 65 μM). Activity observed with glucose was 4-fold greater than with mannose and 50-fold greater than with fructose. The tomato fruit glucokinase was sensitive to product inhibition by ADP (K _i = 36 μM). Little inhibition was observed with glucose 6-phosphate (up to 15 mM) at pH 8.0; however, at pH 7.0 glucokinase activity was inhibited 30–50% by physiological concentrations of glucose 6-phosphate. Received: 4 October 1997 / Accepted: 10 January 1998     

Structure and Function of a Novel Type of ATP-dependent Clp Protease

The Clp protease is conserved among eubacteria and most eukaryotes, and uses ATP to drive protein substrate unfolding and translocation into a chamber of sequestered proteolytic active sites. The main constitutive Clp protease in photosynthetic organisms has evolved into a functionally essential and structurally intricate enzyme. The model Clp protease from the cyanobacterium Synechococcus consists of the HSP100 molecular chaperone ClpC and a mixed proteolytic core comprised of two distinct subunits, ClpP3 and ClpR. We have purified the ClpP3/R complex, the first for a Clp proteolytic core comprised of heterologous subunits. The ClpP3/R complex has unique functional and structural features, consisting of twin heptameric rings each with an identical ClpP3₃ClpR₄ configuration. As predicted by its lack of an obvious catalytic triad, the ClpR subunit is shown to be proteolytically inactive. Interestingly, extensive modification to ClpR to restore proteolytic activity to this subunit showed that its presence in the core complex is not rate-limiting for the overall proteolytic activity of the ClpCP3/R protease. Altogether, the ClpP3/R complex shows remarkable similarities to the 20 S core of the proteasome, revealing a far greater degree of convergent evolution than previously thought between the development of the Clp protease in photosynthetic organisms and that of the eukaryotic 26 S proteasome.Proteases perform numerous tasks vital for cellular homeostasis in all organisms. Much of the selective proteolysis within living cells is performed by multisubunit chaperone-protease complexes. These proteases all share a common two-component architecture and mode of action, with one of the best known examples being the proteasome in archaebacteria, certain eubacteria, and eukaryotes (1).The 20 S proteasome is a highly conserved cylindrical structure composed of two distinct types of subunits, α and β. These are organized in four stacked heptameric rings, with two central β-rings sandwiched between two outer α-rings. Although the α- and β-protein sequences are similar, it is only the latter that is proteolytic active, with a single Thr active site at the N terminus. The barrel-shaped complex is traversed by a central channel that widens up into three cavities. The catalytic sites are positioned in the central chamber formed by the β-rings, adjacent to which are two antechambers conjointly built up by β- and α-subunits. In general, substrate entry into the core complex is essentially blocked by the α-rings, and thus relies on the associating regulatory partner, PAN and 19 S complexes in archaea and eukaryotes, respectively (1). Typically, the archaeal core structure is assembled from only one type of α- and β-subunit, so that the central proteolytic chamber contains 14 catalytic active sites (2). In contrast, each ring of the eukaryotic 20 S complex has seven distinct α- and β-subunits. Moreover, only three of the seven β-subunits in each ring are proteolytically active (3). Having a strictly conserved architecture, the main difference between the 20 S proteasomes is one of complexity. In mammalian cells, the three constitutive active subunits can even be replaced with related subunits upon induction by γ-interferon to generate antigenic peptides presented by the class 1 major histocompatibility complex (4).Two chambered proteases architecturally similar to the proteasome also exist in eubacteria, HslV and ClpP. HslV is commonly thought to be the prokaryotic counterpart to the 20 S proteasome mainly because both are Thr proteases. A single type of HslV protein, however, forms a proteolytic chamber consisting of twin hexameric rather than heptameric rings (5). Also displaying structural similarities to the proteasome is the unrelated ClpP protease. The model Clp protease from Escherichia coli consists of a proteolytic ClpP core flanked on one or both sides by the ATP-dependent chaperones ClpA or ClpX (6). The ClpP proteolytic chamber is comprised of two opposing homo-heptameric rings with the catalytic sites harbored within (7). ClpP alone displays only limited peptidase activity toward short unstructured peptides (8). Larger native protein substrates need to be recognized by ClpA or ClpX and then translocated in an unfolded state into the ClpP proteolytic chamber (9, 10). Inside, the unfolded substrate is bound in an extended manner to the catalytic triads (Ser-97, His-122, and Asp-171) and degraded into small peptide fragments that can readily diffuse out (11). Several adaptor proteins broaden the array of substrates degraded by a Clp protease by binding to the associated HSP100 partner and modifying its protein substrate specificity (12, 13). One example is the adaptor ClpS that interacts with ClpA (EcClpA) and targets N-end rule substrates for degradation by the ClpAP protease (14).Like the proteasome, the Clp protease is found in a wide variety of organisms. Besides in all eubacteria, the Clp protease also exist in mammalian and plant mitochondria, as well as in various plastids of algae and plants. It also occurs in the unusual plastid in Apicomplexan protozoan (15), a family of parasites responsible for many important medical and veterinary diseases such as malaria. Of all these organisms, photobionts have by far the most diverse array of Clp proteins. This was first apparent in cyanobacteria, with the model species Synechococcus elongatus having 10 distinct Clp proteins, four HSP100 chaperones (ClpB1–2, ClpC, and ClpX), three ClpP proteins (ClpP1–3), a ClpP-like protein termed ClpR, and two adaptor proteins (ClpS1–2) (16). Of particular interest is the ClpR variant, which has protein sequence similarity to ClpP but appears to lack the catalytic triad of Ser-type proteases (17). This diversity of Clp proteins is even more extreme in photosynthetic eukaryotes, with at least 23 different Clp proteins in the higher plant Arabidopsis thaliana, most of which are plastid-localized (18).We have recently shown that two distinct Clp proteases exist in Synechococcus, both of which contain mixed proteolytic cores. The first consists of ClpP1 and ClpP2 subunits, and associates with ClpX, whereas the other has a proteolytic core consisting of ClpP3 and ClpR that binds to ClpC, as do the two ClpS adaptors (19). Of these proteases, it is the more constitutively abundant ClpCP3/R that is essential for cell viability and growth (20, 21). It is also the ClpP3/R complex that is homologous to the single type in eukaryotic plastids, all of which also have ClpC as the chaperone partner (16). In algae and plants, however, the complexity of the plastidic Clp proteolytic core has evolved dramatically. In Arabidopsis, the core complex consists of five ClpP and four ClpR paralogs, along with two unrelated Clp proteins unique to higher plants (22). Like ClpP3/R, the plastid Clp protease in Arabidopsis is essential for normal growth and development, and appears to function primarily as a housekeeping protease (23, 24).One of the most striking developments in the Clp protease in photosynthetic organisms and Apicomplexan parasites is the inclusion of ClpR within the central proteolytic core. Although this type of Clp protease has evolved into a vital enzyme, little is known about its activity or the exact role of ClpR within the core complex. To address these points we have purified the intact Synechococcus ClpP3/R proteolytic core by co-expression in E. coli. The recombinant ClpP3/R forms a double heptameric ring complex, with each ring having a specific ClpP3/R stoichiometry and arrangement. Together with ClpC, the ClpP3/R complex degrades several polypeptide substrates, but at a rate considerably slower than that by the E. coli ClpAP protease. Interestingly, although ClpR is shown to be proteolytically inactive, its inclusion in the core complex is not rate-limiting to the overall activity of the ClpCP3/R protease. In general, the results reveal remarkable similarities between the evolutionary development of the Clp protease in photosynthetic organisms and the eukaryotic proteasome relative to their simpler prokaryotic counterparts.