ATP-dependent FtsH and Lon chloroplast proteases

Arabidopsis thaliana proteome contains 667 proteases; some tens of them are chloroplast-targeted proteins, encoded by genes orthologous to the ones coding for bacterial proteolytic enzymes. It is thought that chloroplast proteases are involved in chloroplasts' proteins turnover and quality control (maturation of nucleus-encoded proteins and removal of nonfunctional ones). Some ATP-dependent chloroplast proteases belonging to FtsH family (especially FtsH2 and FtsH5) are considered to be involved in numerous aspects of chloroplast and whole plant maintenance under non-stressing as well as stressing conditions. This notion is supported by severe phenotype appearance of mutants deficient in these proteases. In contrast to seemingly high physiological importance of chloroplast members of FtsH protease family, only a few individual proteins have been identified so far as their physiological targets (i.e. Lhcb1, Lhcb3, PsbA and Rieske protein). Our knowledge regarding structure and molecular mechanisms of these enzymes' action is limited when compared with what is known about FtsHs of bacterial origin. Equally limited is the knowledge about ATP-dependent Lon4 protease being the single known chloroplast-targeted ortholog of Lon protease of Escherichia coli.     

The significance of Arabidopsis AAA proteases for activity and assembly/stability of mitochondrial OXPHOS complexes

The Arabidopsis genome encodes four mitochondrially localized adenosine 5'-triphosphate-dependent metalloproteases called FtsH or AAA proteases. All of them span the inner mitochondrial membrane but the catalytic site of two of them (AtFtsH4 and AtFtsH11) faces the intermembrane space, while AtFtsH3 and AtFtsH10 face the matrix. We used a combination of blue-native polyacrylamide gel electrophoresis and histochemical staining to reveal the consequences of the loss of one of mitochondrial FtsHs on the efficiency of the oxidative phosphorylation system in Arabidopsis mitochondria. To address this issue, we have selected homozygous lines of respective transferred DNA (T-DNA) insertional mutants. A decrease in the activity of complexes I and V but not complex IV was observed in the ftsh mutants, except for the mutant lacking functional FtsH11. The reduced activity of complexes I and V was well correlated with a decreased protein level of these complexes. Western blots experiments using specific antibodies against complex V subunits showed a significant reduction of these subunits only in the ftsh4 mutant. Taken together, our results reveal a role of FtsH3, FtsH4 and FtsH10 proteases in the biogenesis of a plant oxidative phosphorylation system.     

Flavodoxin, a new fluorescent substrate for monitoring proteolytic activity of FtsH lacking a robust unfolding activity

Escherichia coli FtsH, which belongs to the ATPases associated with diverse cellular activities (AAA) family, is an ATP-dependent and membrane-bound protease. FtsH degrades misassembled membrane proteins and a subset of cytoplasmic regulatory proteins. To elucidate the molecular mechanisms of the proteolysis, a system for precisely monitoring substrate degradation is required. We have exploited E. coli flavodoxin containing non-covalently bound flavin mononucleotide (FMN) as a model substrate for monitoring protein degradation. It was found that FtsH degrades FMN-free apo-flavodoxin but not holo-flavodoxin. However, degradation of a mutant flavodoxin carrying a substitution of Tyr94 to Asp with a lower affinity for FMN could be monitored by fluorimetry. This newly developed monitoring system will also be applicable for proteolysis by other ATP-dependent proteases.     

Characterization of mutants of the Escherichia coli AAA protease, FtsH, carrying a mutation in the central pore region

Escherichia coli FtsH is an ATP-dependent and membrane-bound protease, which belongs to the ATPases associated with diverse cellular activities family. FtsH degrades a subset of cytoplasmic regulatory proteins and misassembled membrane proteins. It has been proposed that ATP-dependent proteases unfold and translocate substrate proteins into the protease chamber. Previously, we reported that Phe228 and Gly230 in the conserved motif, @XG (where @ is an aromatic residue and X is any residue), in the central pore of the FtsH ATPase ring have important roles in proteolysis and its coupling to ATP hydrolysis. In this paper, we constructed and characterized additional pore mutants. Results indicated that certain acidic residues located in the pore region are also important for the activity of FtsH. Proteolytic activities of most mutants are correlated with their ATPase activities. Evidence also indicated that Val229, the 2nd residue of the @XG motif, may have a substrate-specific role.     

The balance between protein synthesis and degradation in chloroplasts determines leaf variegation in Arabidopsis yellow variegated mutants

An Arabidopsis thaliana leaf-variegated mutant yellow variegated2 (var2) results from loss of FtsH2, a major component of the chloroplast FtsH complex. FtsH is an ATP-dependent metalloprotease in thylakoid membranes and degrades several chloroplastic proteins. To understand the role of proteolysis by FtsH and mechanisms leading to leaf variegation, we characterized the second-site recessive mutation fu-gaeri1 (fug1) that suppressed leaf variegation of var2. Map-based cloning and subsequent characterization of the FUG1 locus demonstrated that it encodes a protein homologous to prokaryotic translation initiation factor 2 (cpIF2) located in chloroplasts. We show evidence that cpIF2 indeed functions in chloroplast protein synthesis in vivo. Suppression of leaf variegation by fug1 is observed not only in var2 but also in var1 (lacking FtsH5) and var1 var2. Thus, suppression of leaf variegation caused by loss of FtsHs is most likely attributed to reduced protein synthesis in chloroplasts. This hypothesis was further supported by the observation that another viable mutation in chloroplast translation elongation factor G also suppresses leaf variegation in var2. We propose that the balance between protein synthesis and degradation is one of the determining factors leading to the variegated phenotype in Arabidopsis leaves.     

Coupled kinetics of ATP and peptide hydrolysis by Escherichia coli FtsH protease

FtsH from Escherichia coli is an ATP- and Zn(2+)-dependent integral membrane protease that is involved in the degradation of regulatory proteins such as sigma(32) and uncomplexed subunits of membrane protein complexes such as secY of the protein translocase. We describe a protocol for solubilizing the recombinant enzyme from inclusion bodies and its subsequent refolding and purification to near homogeneity. This is a high-yield protocol and produces in excess of 20 mg of purified FtsH per liter of E. coli culture. We found that refolded FtsH has biochemical properties similar to detergent extracted overexpressed protein described previously. FtsH forms a large complex with an apparent mass of 1200 kDa as determined by gel filtration. Both ATPase and protease activities are coincident with this large complex; smaller forms of FtsH do not exhibit either activity. While FtsH-catalyzed hydrolysis of ATP can occur in the absence of protein substrate (k(c) = 22 min(-1); K(m) = 23 microM), proteolysis shows an absolute dependence on nucleoside-5'-triphosphates, including ATP, CTP, and various analogues. In the presence of 5 mM ATP, FtsH catalyzes the hydrolysis of sigma(32) with the following observed kinetic parameters: k(c) = 0.18 min(-1) and K(m) = 8.5 microM. Significantly, this reaction is processive and generates no intermediate species, but rather, approximately 10 peptide products, all of MW <3 kDa. FtsH protease also efficiently hydrolyzes the peptide Phe-Gly-His-(NO)2Phe-Phe-Ala-Phe-OMe. Hydrolysis occurs exclusively at the (NO)2Phe-Phe bond (k(c) = 2.1 min(-1); K(m) = 12 microM), and like proteolysis, shows an absolute dependence on NTPs. We propose a mechanism for the coupled hydrolytic activities of FtsH toward ATP and peptide substrates that is consistent with a recently proposed structural model for FtsH.     

Structure and function of the bacterial AAA protease FtsH

Proteolysis of regulatory proteins or key enzymes of biosynthetic pathways is a universal mechanism to rapidly adjust the cellular proteome to particular environmental needs. Among the five energy-dependent AAA(+) proteases in Escherichia coli, FtsH is the only essential protease. Moreover, FtsH is unique owing to its anchoring to the inner membrane. This review describes the structural and functional properties of FtsH. With regard to its role in cellular quality control and regulatory circuits, cytoplasmic and membrane substrates of the FtsH protease are depicted and mechanisms of FtsH-dependent proteolysis are discussed.     

The Escherichia coli plasma membrane contains two PHB (prohibitin homology) domain protein complexes of opposite orientations

Two membrane proteases, FtsH and HtpX, are jointly essential for Escherichia coli cell viability, presumably through their abilities to degrade abnormal membrane proteins. To search for additional cellular factors involved in membrane protein quality control, we isolated multicopy suppressors that alleviated the growth defect of the ftsH/htpX dual disruption mutant. One of them was ybbK, which is renamed qmcA, encoding a membrane-bound prohibitin homology (PHB) domain family protein. Multicopy suppression was also observed with hflK-hflC, encoding another set of PHB domain membrane proteins, which had been known to form a complex (HflKC) and to interact with FtsH. Whereas the DeltaftsH sfhC21 (a viability defect suppressor for DeltaftsH) strain exhibited temperature sensitivity in the presence of cAMP, additional disruption of both qmcA and hflK-hflC exaggerated the growth defect. Pull-down and sedimentation experiments showed that QmcA, like HflKC, forms an oligomer and interacts with FtsH. Protease accessibility assays revealed that QmcA, unlike periplasmically exposed HflKC, possesses a cytoplasmically disposed large C-terminal domain, thus assuming the type I (NOUT-CIN) orientation. We discuss possible significance of having PHB domains on both sides of the membrane.     

A rule governing the FtsH-mediated proteolysis of the MgtC virulence protein from <Emphasis Type="Italic">Salmonella enterica</Emphasis> serovar Typhimurium

A tightly controlled turnover of membrane proteins is required for lipid bilayer stability, cell metabolism, and cell viability. Among the energy-dependent AAA⁺ proteases in Salmonella, FtsH is the only membrane-bound protease that contributes to the quality control of membrane proteins. FtsH preferentially degrades the C-terminus or N-terminus of misfolded, misassembled, or damaged proteins to maintain physiological functions. We found that FtsH hydrolyzes the Salmonella MgtC virulence protein when we substitute the MgtC 226^th Trp, which is well conserved in other intracellular pathogens and normally protects MgtC from the FtsH-mediated proteolysis. Here we investigate a rule determining the FtsH-mediated proteolysis of the MgtC protein at Trp226 residue. Substitution of MgtC tryptophan 226^th residue to alanine, glycine, or tyrosine leads to MgtC proteolysis in a manner dependent on the FtsH protease whereas substitution to phenylalanine, methionine, isoleucine, leucine, or valine resists MgtC degradation by FtsH. These data indicate that a large and hydrophobic side chain at 226^th residue is required for protection from the FtsH-mediated MgtC proteolysis.     

Cooperative D1 Degradation in the Photosystem II Repair Mediated by Chloroplastic Proteases in Arabidopsis

Light energy constantly damages photosynthetic apparatuses, ultimately causing impaired growth. Particularly, the sessile nature of higher plants has allowed chloroplasts to develop unique mechanisms to alleviate the irreversible inactivation of photosynthesis. Photosystem II (PSII) is known as a primary target of photodamage. Photosynthetic organisms have evolved the so-called PSII repair cycle, in which a reaction center protein, D1, is degraded rapidly in a specific manner. Two proteases that perform processive or endopeptidic degradation, FtsH and Deg, respectively, participate in this cycle. To examine the cooperative D1 degradation by these proteases, we engaged Arabidopsis (Arabidopsis thaliana) mutants lacking FtsH2 (yellow variegated2 [var2]) and Deg5/Deg8 (deg5 deg8) in detecting D1 cleaved fragments. We detected several D1 fragments only under the var2 background, using amino-terminal or carboxyl-terminal specific antibodies of D1. The appearance of these D1 fragments was inhibited by a serine protease inhibitor and by deg5 deg8 mutations. Given the localization of Deg5/Deg8 on the luminal side of thylakoid membranes, we inferred that Deg5/Deg8 cleaves D1 at its luminal loop connecting the transmembrane helices C and D and that the cleaved products of D1 are the substrate for FtsH. These D1 fragments detected in var2 were associated with the PSII monomer, dimer, and partial disassembly complex but not with PSII supercomplexes. It is particularly interesting that another processive protease, Clp, was up-regulated and appeared to be recruited from stroma to the thylakoid membrane in var2, suggesting compensation for FtsH deficiency. Together, our data demonstrate in vivo cooperative degradation of D1, in which Deg cleavage assists FtsH processive degradation under photoinhibitory conditions.     

The thylakoid lumen protease Deg1 is involved in the repair of photosystem II from photoinhibition in Arabidopsis

Deg1 is a Ser protease peripherally attached to the lumenal side of the thylakoid membrane. Its physiological function is unknown, but its localization makes it a suitable candidate for participation in photoinhibition repair by degradation of the photosystem II reaction center protein D1. We transformed Arabidopsis thaliana with an RNA interference construct and obtained plants with reduced levels of Deg1. These plants were smaller than wild-type plants, flowered earlier, were more sensitive to photoinhibition, and accumulated more of the D1 protein, probably in an inactive form. Two C-terminal degradation products of the D1 protein, of 16 and 5.2 kD, accumulated at lower levels compared with the wild type. Moreover, addition of recombinant Deg1 to inside-out thylakoid membranes isolated from the mutant could induce the formation of the 5.2-kD D1 C-terminal fragment, whereas the unrelated proteases trypsin and thermolysin could not. Immunoblot analysis revealed that mutants containing less Deg1 also contain less FtsH protease, and FtsH mutants contain less Deg1. These results suggest that Deg1 cooperates with the stroma-exposed proteases FtsH and Deg2 in degrading D1 protein during repair from photoinhibition by cleaving lumen-exposed regions of the protein. In addition, they suggest that accumulation of Deg1 and FtsH proteases may be coordinated.     

FtsH is involved in the early stages of repair of photosystem II in Synechocystis sp PCC 6803

When plants, algae, and cyanobacteria are exposed to excessive light, especially in combination with other environmental stress conditions such as extreme temperatures, their photosynthetic performance declines. A major cause of this photoinhibition is the light-induced irreversible photodamage to the photosystem II (PSII) complex responsible for photosynthetic oxygen evolution. A repair cycle operates to selectively replace a damaged D1 subunit within PSII with a newly synthesized copy followed by the light-driven reactivation of the complex. Net loss of PSII activity occurs (photoinhibition) when the rate of damage exceeds the rate of repair. The identities of the chaperones and proteases involved in the replacement of D1 in vivo remain uncertain. Here, we show that one of the four members of the FtsH family of proteases (cyanobase designation slr0228) found in the cyanobacterium Synechocystis sp PCC 6803 is important for the repair of PSII and is vital for preventing chronic photoinhibition. Therefore, the ftsH gene family is not functionally redundant with respect to the repair of PSII in this organism. Our data also indicate that FtsH binds directly to PSII, is involved in the early steps of D1 degradation, and is not restricted to the removal of D1 fragments. These results, together with the recent analysis of ftsH mutants of Arabidopsis, highlight the critical role played by FtsH proteases in the removal of damaged D1 from the membrane and the maintenance of PSII activity in vivo.     

Length recognition at the N-terminal tail for the initiation of FtsH-mediated proteolysis

FtsH-mediated proteolysis against membrane proteins is processive, and presumably involves dislocation of the substrate into the cytosol where the enzymatic domains of FtsH reside. To study how such a mode of proteolysis is initiated, we manipulated N-terminal cytosolic tails of three membrane proteins. YccA, a natural substrate of FtsH was found to require the N-terminal tail of 20 amino acid residues or longer to be degraded by FtsH in vivo. Three unrelated sequences of this segment conferred the FtsH sensitivity to YccA. An artificially constructed TM9-PhoA protein, derived from SecY, as well as the SecE protein, were sensitized to FtsH by addition of extra amino acid sequences to their N-terminal cytosolic tails. Thus, FtsH recognizes a cytosolic region of sufficient length (~20 amino acids) to initiate the processive proteolysis against membrane proteins. Such a region is typically at the N-terminus and can be diverse in amino acid sequences.     

Early emergence of the FtsH proteases involved in photosystem II repair

Efficient degradation of damaged D1 during the repair of PSII is carried out by a set of dedicated FtsH proteases in the thylakoid membrane. Here we investigated whether the evolution of FtsH could hold clues to the origin of oxygenic photosynthesis. A phylogenetic analysis of over 6000 FtsH protease sequences revealed that there are three major groups of FtsH proteases originating from gene duplication events in the last common ancestor of bacteria, and that the FtsH proteases involved in PSII repair form a distinct clade branching out before the divergence of FtsH proteases found in all groups of anoxygenic phototrophic bacteria. Furthermore, we showed that the phylogenetic tree of FtsH proteases in phototrophic bacteria is similar to that for Type I and Type II reaction centre proteins. We conclude that the phylogeny of FtsH proteases is consistent with an early origin of photosynthetic water oxidation chemistry.     

Resolving individual steps in the operation of ATP-dependent proteolytic molecular machines: from conformational changes to substrate translocation and processivity

Clp, Lon, and FtsH proteases are proteolytic molecular machines that use the free energy of ATP hydrolysis to unfold protein substrates and processively present them to protease active sites. Here we review recent biochemical and structural studies relevant to the mechanism of ATP-dependent processive proteolysis. Despite the significant structural differences among the Clp, Lon, and FtsH proteases, these enzymes share important mechanistic features. In these systems, mechanistic studies have provided evidence for ATP binding and hydrolysis-driven conformational changes that drive translocation of substrates, which has significant implications for the processive mechanism of proteolysis. These studies indicate that the nucleotide (ATP, ADP, or nonhydrolyzable ATP analogues) occupancy of the ATPase binding sites can influence the binding mode and/or binding affinity for protein substrates. A general mechanism is proposed in which the communication between ATPase active sites and protein substrate binding regions coordinates a processive cycle of substrate binding, translocation, proteolysis, and product release.     

Lack of a robust unfoldase activity confers a unique level of substrate specificity to the universal AAA protease FtsH

FtsH, a member of the AAA family of proteins, is the only membrane ATP-dependent protease universally conserved in prokaryotes, and the only essential ATP-dependent protease in Escherichia coli. We investigated the mechanism of degradation by FtsH. Other well-studied ATP-dependent proteases use ATP to unfold their substrates. In contrast, both in vitro and in vivo studies indicate that degradation by FtsH occurs efficiently only when the substrate is a protein of low intrinsic thermodynamic stability. Because FtsH lacks robust unfoldase activity, it is able to use the protein folding state of substrates as a criterion for degradation. This feature may be key to its role in the cell and account for its ubiquitous distribution among prokaryotic organisms.     

Caspases - controlling intracellular signals by protease zymogen activation

Animal development and homeostasis is a balance between cell proliferation and cell death. Physiologic, and sometimes pathologic, cell death - apoptosis - is driven by activation of a family of proteases known as the caspases, present in almost all nucleated animal cells. The enzymatic properties of these proteases are governed by a dominant specificity for substrates containing Asp, and by the use of a Cys side chain for catalyzing peptide bond cleavage. The primary specificity for Asp turns out to be very rare among proteases, and currently the only other known mammalian proteases with the same primary specificity is the physiological caspase activator granzyme B. Like most other proteases, the caspases are synthesized as inactive zymogens whose activation requires limited proteolysis or binding to co-factors. To transmit the apoptotic execution signal, caspase zymogens are sequentially activated through either an intrinsic or an extrinsic pathway. The activation of caspases at the apex of each pathway, the initiators, occurs by recruitment to specific adapter molecules through homophilic interaction domains, and the activated initiators directly process the executioner caspases to their catalytically active forms. In the present communication we review the different mechanisms underlying the selective activation of the caspases.     

Dislocation of membrane proteins in FtsH-mediated proteolysis.

Escherichia coli FtsH degrades several integral membrane proteins, including YccA, having seven transmembrane segments, a cytosolic N-terminus and a periplasmic C-terminus. Evidence indicates that FtsH initiates proteolysis at the N-terminal cytosolic domain. SecY, having 10 transmembrane segments, is also a substrate of FtsH. We studied whether and how the FtsH-catalyzed proteolysis on the cytosolic side continues into the transmembrane and periplasmic regions using chimeric proteins, YccA-(P3)-PhoA-His6-Myc and SecY-(P5)-PhoA, with the alkaline phosphatase (PhoA) mature sequence in a periplasmic domain. The PhoA domain that was present within the fusion protein was rapidly degraded by FtsH when it lacked the DsbA-dependent folding. In contrast, both PhoA itself and the TM9-PhoA region of SecY-(P5)-PhoA were stable when expressed as independent polypeptides. In the presence of DsbA, the FtsH-dependent degradation stopped at a site near to the N-terminus of the PhoA moiety, leaving the PhoA domain (and its C-terminal region) undigested. The efficiency of this degradation stop correlated well with the rapidity of the folding of the PhoA domain. Thus, both transmembrane and periplasmic domains are degraded by the processive proteolysis by FtsH, provided they are not tightly folded. We propose that FtsH dislocates the extracytoplasmic domain of a substrate, probably using its ATPase activity.