Positively-Charged Semi-Tunnel Is a Structural and Surface Characteristic of Polyphosphate-Binding Proteins: An In-Silico Study

Phosphate is essential for all major life processes, especially energy metabolism and signal transduction. A linear phosphate polymer, polyphosphate (polyP), linked by high-energy phosphoanhydride bonds, can interact with various proteins, playing important roles as an energy source and regulatory factor. However, polyP-binding structures are largely unknown. Here we proposed a putative polyP binding site, a positively-charged semi-tunnel (PCST), identified by surface electrostatics analyses in polyP kinases (PPKs) and many other polyP-related proteins. We found that the PCSTs in varied proteins were folded in different secondary structure compositions. Molecular docking calculations revealed a significant value for binding affinity to polyP in PCST-containing proteins. Utilizing the PCST identified in the β subunit of PPK3, we predicted the potential polyP-binding domain of PPK3. The discovery of this feature facilitates future searches for polyP-binding proteins and discovery of the mechanisms for polyP-binding activities. This should greatly enhance the understanding of the many physiological functions of protein-bound polyP and the involvement of polyP and polyP-binding proteins in various human diseases.     

Lon recognition of the replication initiator DnaA requires a bipartite degron

DnaA initiates chromosome replication in bacteria. In Caulobacter crescentus, the Lon protease degrades DnaA to coordinate replication with nutrient availability and to halt the cell cycle during acute stress. Here, we characterize the mechanism of DnaA recognition by Lon. We find that the folded state of DnaA appears crucial for its degradation, in contrast to the well‐known role of Lon in degrading misfolded proteins. We fail to identify a single degradation motif (degron) sufficient for DnaA degradation, rather we show that both the ATPase domain and a species‐specific N‐terminal motif are important for productive Lon degradation of full‐length DnaA. Mutations in either of these determinants disrupt DnaA degradation in vitro and in vivo. However, analysis of truncation products reveals that appending other extensions to the ATPase domain is sufficient to trigger degradation, suggesting plasticity in Lon recognition. Our final working model is that Lon engages DnaA through at least two elements, one of which anchors DnaA to Lon and the other acting as an initiation site for degradation.     

A membrane-bound archaeal Lon protease displays ATP-independent proteolytic activity towards unfolded proteins and ATP-dependent activity for folded proteins

In contrast to the eucaryal 26S proteasome and the bacterial ATP-dependent proteases, little is known about the energy-dependent proteolysis in members of the third domain, Archae. We cloned a gene homologous to ATP-dependent Lon protease from a hyperthermophilic archaeon and observed the unique properties of the archaeal Lon. Lon from Thermococcus kodakaraensis KOD1 (Lon(Tk)) is a 70-kDa protein with an N-terminal ATPase domain belonging to the AAA(+) superfamily and a C-terminal protease domain including a putative catalytic triad. Interestingly, a secondary structure prediction suggested the presence of two transmembrane helices within the ATPase domain and Western blot analysis using specific antiserum against the recombinant protein clearly indicated that Lon(Tk) was actually a membrane-bound protein. The recombinant Lon(Tk) possessed thermostable ATPase activity and peptide cleavage activity toward fluorogenic peptides with optimum temperatures of 95 and 70 degrees C, respectively. Unlike the enzyme from Escherichia coli, we found that Lon(Tk) showed higher peptide cleavage activity in the absence of ATP than it did in the presence of ATP. When three kinds of proteins with different thermostabilities were examined as substrates, it was found that Lon(Tk) required ATP for degradation of folded proteins, probably due to a chaperone-like function of the ATPase domain, along with ATP hydrolysis. In contrast, Lon(Tk) degraded unfolded proteins in an ATP-independent manner, suggesting a mode of action in Lon(Tk) different from that of its bacterial counterpart.     

Helicase binding to DnaI exposes a cryptic DNA-binding site during helicase loading in Bacillus subtilis

The Bacillus subtilis DnaI, DnaB and DnaD proteins load the replicative ring helicase DnaC onto DNA during priming of DNA replication. Here we show that DnaI consists of a C-terminal domain (Cd) with ATPase and DNA-binding activities and an N-terminal domain (Nd) that interacts with the replicative ring helicase. A Zn²⁺-binding module mediates the interaction with the helicase and C67, C70 and H84 are involved in the coordination of the Zn²⁺. DnaI binds ATP and exhibits ATPase activity that is not stimulated by ssDNA, because the DNA-binding site on Cd is masked by Nd. The ATPase activity resides on the Cd domain and when detached from the Nd domain, it becomes sensitive to stimulation by ssDNA because its cryptic DNA-binding site is exposed. Therefore, Nd acts as a molecular ‘switch’ regulating access to the ssDNA binding site on Cd, in response to binding of the helicase. DnaI is sufficient to load the replicative helicase from a complex with six DnaI molecules, so there is no requirement for a dual helicase loader system.     

The regulatory function of N-terminal AAA+ ATPase domain of eukaryote-like archaeal Orc1/Cdc6 protein during DNA replication initiation

Archaeal replication machinery represents a core version of this in eukaryotes. The crenarchaeon Sulfolobus solfataricus has the potential to be a powerful model system to understand the central mechanism of eukaryotic DNA replication because it contains three active origins of replication and three eukaryote-like Orc1/Cdc6 proteins (SsoCdc6-1, SsoCdc6-2, and SsoCdc6-3). In this study, we investigate the DNA-binding activities of the N-terminal AAA⁺ ATPase domains of these Orc1/Cdc6 proteins, including their functional interactions with the other SsoCdc6 proteins, on duplex DNA substrates derived from the origins of S. solfataricus. We showed that the ATPase domain of SsoCdc6-2 retained to a great extent the origin DNA-binding activity, and likewise maintained its stimulating effect on SsoCdc6-3. Second, the ATPase domain of SsoCdc6-1, which also stimulated the DNA-binding ability of SsoCdc6-3, demonstrated a significantly improved DNA-binding activity at the forked substrate, but only showed a very weak ability towards the blunt DNA. Third, the ATPase domain of SsoCdc6-3, although having lost much of its DNA-binding activity from the origin, inhibited both SsoCdc6-1 and SsoCdc6-2. These imply that the N-terminal AAA⁺ ATPase domain of archaeal Orc1/Cdc6 protein could be differentially involved in origin recognition during DNA replication initiation even if lacking conventional C-terminal winged helix DNA-binding elements. Our findings further propose that conserved AAA⁺ ATPase domains of Orc1/Cdc6 proteins determine their defined and coordinated functions not only in the archaeon species but also in eukaryotes during the early events of DNA replication.     

Opposing effects of DNA on proteolysis of a replication initiator

DNA replication initiation proteins (Reps) are subjected to degradation by cellular proteases. We investigated how the formation of nucleoprotein complex, involving Rep and a protease, affects Rep degradation. All known Escherichia coli AAA+ cytosolic proteases and the replication initiation protein TrfA of the broad-host-range plasmid RK2 were used. Our results revealed that DNA influences the degradation process and that the observed effects are opposite and protease specific. In the case of ClpXP and ClpYQ proteases, DNA abolishes proteolysis, while in the case of ClpAP and Lon proteases it stimulates the process. ClpX and ClpY cannot interact with DNA-bound TrfA, while the ClpAP and Lon activities are enhanced by the formation of nucleoprotein complexes involving both the protease and TrfA. Lon has to interact with TrfA before contacting DNA, or this interaction can occur with TrfA already bound to DNA. The TrfA degradation by Lon can be carried out only on DNA. The absence of Lon results with higher stability of TrfA in the cell.     

A polyphosphate-lon protease complex in the adaptation of Escherichia coli to amino acid starvation

Cells must balance energy-efficient growth with the ability to adapt rapidly to sudden changes in their environment. For example, in an environment rich in amino acids, cells do not expend energy for making amino acid biosynthetic enzymes. However, if the environment becomes depleted of amino acids (nutritional downshift), cells will be exposed to a lack of both the amino acid biosynthetic enzymes and the amino acids required to make these enzymes. To solve this dilemma, cells must use their own proteins as sources of amino acids in response to the nutritional downshift. Once amino acid biosynthetic enzymes start to accumulate, the cell is able to produce its own amino acids, and a new growth phase begins. In Escherichia coli, amino acid starvation leads to the accumulation of an unusual molecule, polyphosphate (polyP), a linear polymer of many hundreds of orthophosphate residues. Protein degradation in this bacterium appears to be triggered by the accumulation of polyP. PolyP forms a complex with the ATP-dependent Lon protease. The formation of a complex then enables Lon to degrade free ribosomal proteins. Certain very abundant ribosomal proteins can be the sacrificial substrates targeted for degradation at the onset of the downshift. Here I propose to call the polyP-Lon complex the "stringent protease," and I discuss new insights of protein degradation control in bacteria.     

Functional domains of Brevibacillus thermoruber lon protease for oligomerization and DNA binding: role of N-terminal and sensor and substrate discrimination domains

Lon protease is a multifunctional enzyme, and its functions include the degradation of damaged proteins and naturally short lived proteins, ATPase and chaperone-like activities, as well as DNA binding. A thermostable Lon protease from Brevibacillus thermoruber WR-249 (Bt-Lon) has been cloned and characterized with an N-terminal domain, a central ATPase domain that includes a sensor and substrate discrimination (SSD) domain, and a C-terminal protease domain. Here we present a detailed structure-function characterization of Bt-Lon, not only dissecting the individual roles of Bt-Lon domains in oligomerization, catalytic activities, chaperone-like activity, and DNA binding activity but also describing the nature of oligomerization. Seven truncated mutants of Bt-Lon were designed, expressed, and purified. Our results show that the N-terminal domain is essential for oligomerization. The truncation of the N-terminal domain resulted in the failure of oligomerization and led to the inactivation of proteolytic, ATPase, and chaperone-like activities but retained the DNA binding activity, suggesting that oligomerization of Bt-Lon is a prerequisite for its catalytic and chaperone-like activities. We further found that the SSD is involved in DNA binding based on gel mobility shift assays. On the other hand, the oligomerization of Bt-Lon proceeds through a dimer <--> tetramer <--> hexamer assembly model revealed by chemical cross-linking experiments. The results also showed that hydrophobic interactions may play important roles in the dimerization of Bt-Lon, and ionic interactions are mainly responsible for the assembly of hexamers.     

The Thermoplasma acidophilum Lon protease has a Ser-Lys dyad active site.

A gene with significant similarity to bacterial Lon proteases was identified during the sequencing of the genome of the thermoacidophilic archaeon Thermoplasma acidophilum. Protein sequence comparison revealed that Thermoplasma Lon protease (TaLon) is more similar to the LonB proteases restricted to Gram-positive bacteria than to the widely distributed bacterial LonA. However, the active site residues of the protease and ATPase domain are highly conserved in all Lon proteases. Using site-directed mutagenesis we show here that TaLon and EcLon, and probably all other Lon proteases, contain a Ser-Lys dyad active site. The TaLon active site mutants were fully assembled and, similar to TaLon wild-type, displayed an apparent molar mass of 430 kDa upon gelfiltration. This would be consistent with a hexameric complex and indeed electron micrographs of TaLon revealed ring-shaped particles, although of unknown symmetry. Comparison of the ATPase activity of Lon wild-type from Thermoplasma or Escherichia coli with respective protease active site mutants revealed differences in Km and V values. This suggests that in the course of protein degradation by wild-type Lon the protease domain might influence the activity of the ATPase domain.     

DNA-binding specificity of the Lon protease α-domain from Brevibacillus thermoruber WR-249

Lon protease has been well studied in many aspects; however, the DNA-binding specificity of Lon in prokaryotes has not been clearly identified. Here we examined the DNA-binding activity of Lon protease α-domains from Brevibacillus thermoruber (Bt), Bacillus subtilis (Bs), and Escherichia coli (Ec). MALDI-TOF mass spectroscopy showed that the α-domain from Bt-Lon binds to the duplex nucleotide sequence 5′-CTGTTAGCGGGC-3′ (ms1) and protected it from DNase I digestion. Surface plasmon resonance showed that the Bt-Lon α-domain binds with ms1 double-stranded DNA tighter than Bs- and Ec-Lon α-domains, whereas the Bt-Lon α-domain has dramatically lower affinity for double-stranded DNA with 0 and 50% identity to the ms1 binding sequence. Our results indicated that Bt-Lon α-domain plays a critical role with ms1 sequence in the DNA-binding specificity.     

DNA-binding properties of the recombinant high-mobility-group-like AT-hook-containing region from human BRG1 protein

The hBRG1 protein, a central ATPase of the human switching/sucrose non-fermenting (SWI/SNF) remodeling complex, has a catalytic ATPase domain, an AT-hook motif and a bromodomain. Bromodomains, found in many chromatin-associated proteins, recognize N-acetyl-lysine in histones and other proteins. The AT-hook motif, first described in the high-mobility group of non-histone chromosomal proteins HMGA1/2, is a DNA-binding motif. The AT-hook binds to the AT-rich DNA sequences in the minor groove of B-DNA in a non-sequence specific manner. AT-hook motifs have been identified in many other DNA-binding proteins. In this study we cloned and purified a fragment of hBRG1 encompassing the AT-hook region and the bromodomain. Nuclear magnetic resonance (NMR) and circular dichroism (CD) analyses show that the recombinant domains are structured. The functionality of subdomains was checked by assessing their interactions with N-acetylated peptides from histones and with DNA. Isothermal titration calorimetric (ITC) analysis demonstrates that the primary micromolar interaction is through the AT-hook motif. The AT-hook region binds to linear DNA by unwinding it. These properties resemble the characteristics of the HMGA1/2 proteins and their interaction with DNA.     

DNA and RNA binding by the mitochondrial lon protease is regulated by nucleotide and protein substrate

The ATP-dependent Lon protease belongs to a unique group of proteases that bind DNA. Eukaryotic Lon is a homo-oligomeric ring-shaped complex localized to the mitochondrial matrix. In vitro, human Lon binds specifically to a single-stranded GT-rich DNA sequence overlapping the light strand promoter of human mitochondrial DNA (mtDNA). We demonstrate that Lon binds GT-rich DNA sequences found throughout the heavy strand of mtDNA and that it also interacts specifically with GU-rich RNA. ATP inhibits the binding of Lon to DNA or RNA, whereas the presence of protein substrate increases the DNA binding affinity of Lon 3.5-fold. We show that nucleotide inhibition and protein substrate stimulation coordinately regulate DNA binding. In contrast to the wild type enzyme, a Lon mutant lacking both ATPase and protease activity binds nucleic acid; however, protein substrate fails to stimulate binding. These results suggest that conformational changes in the Lon holoenzyme induced by nucleotide and protein substrate modulate the binding affinity for single-stranded mtDNA and RNA in vivo. Co-immunoprecipitation experiments show that Lon interacts with mtDNA polymerase gamma and the Twinkle helicase, which are components of mitochondrial nucleoids. Taken together, these results suggest that Lon participates directly in the metabolism of mtDNA.     

Polypeptide stimulators of the Ms-Lon protease

Both the peptidase activity against small fluorescent peptide substrates and the ATPase activity of Lon (La) proteases are stimulated by unstructured proteins such as alpha-casein. This stimulation reveals the simultaneous interaction of Lon with two proteolytic substrates--alpha-casein and the peptide substrate. To understand the cellular function of this stimulation, it is important to determine the physical properties of Lon stimulators. The abilities of compositionally simple random copolymers of amino acids (rcAAs) to stimulate the peptidase and ATPase activities of the Lon protease from Mycobacterium smegmatis (Ms-Lon) and its N-terminal truncation mutant (N-E226) were determined. We report that cationic but not anionic rcAAs stimulated Ms-Lon's peptidase activity but were themselves poor substrates for the enzyme. Peptidase stimulation by rcAAs correlated approximately with the degree of hydrophobicity of these polypeptides and reached levels >10-fold higher than observed previously for Ms-Lon stimulators such as alpha-casein. In contrast to alpha-casein, which stimulates Ms-Lon's peptidase activity by 40% and ATPase activity by 150%, rcAAs stimulated peptidase activity without concomitant stimulation of ATPase activity. Active site labeling experiments suggested that both rcAAs and ATP increased peptidase activity by increasing accessibility to the peptidase active site. Peptidase activity assays in the presence of both alpha-casein and rcAAs revealed that interactions of rcAAs and alpha-casein with Ms-Lon are extremely complex and not mutually exclusive. Specifically, (1) additions of low concentrations of alpha-casein (<50 microg/mL) caused a further stimulation of Ms-Lon's rcAA-stimulated peptidase activity; (2) additions of higher concentrations of alpha-casein inhibited Ms-Lon's rcAA-stimulated peptidase activity; (3) additions of all concentrations of alpha-casein inhibited N-E226's rcAA-stimulated peptidase activity. We conclude the Ms-Lon can interact with an rcAA, alpha-casein, and a substrate peptide simultaneously, and that formation of this quaternary complex requires the N-terminal domain of Ms-Lon. These data support models of Ms-Lon that include two allosteric polypeptide binding sites distinct from the catalytic peptidase site.     

Recent developments in the mechanistic enzymology of the ATP-dependent Lon protease from Escherichia coli: highlights from kinetic studies

Lon protease, also known as protease La, is one of the simplest ATP-dependent proteases that plays vital roles in maintaining cellular functions by selectively eliminating misfolded, damaged and certain short-lived regulatory proteins. Although Lon is a homo-oligomer, each subunit of Lon contains both an ATPase and a protease active site. This relatively simple architecture compared to other hetero-oligomeric ATP-dependent proteases such as the proteasome makes Lon a useful paradigm for studying the mechanism of ATP-dependent proteolysis. In this article, we survey some recent developments in the mechanistic characterization of Lon with an emphasis on the utilization of pre-steady-state enzyme kinetic techniques to determine the timing of the ATPase and peptidase activities of the enzyme.     

N domain of the Lon AAA+ protease controls assembly and substrate choice

Abstract: The protein quality control network (pQC) plays critical roles in maintaining protein and cellular homeostasis, especially during stress. Lon is a major pQC AAA+ protease, conserved from bacteria to human mitochondria. It is the principal enzyme that degrades most unfolded or damaged proteins. Degradation by Lon also controls cellular levels of several key regulatory proteins. Recently, our group determined that Escherichia coli Lon, previously thought to be an obligate homo‐hexamer, also forms a dodecamer. This larger assembly has decreased ATPase activity and displays substrate‐specific alterations in degradation compared with the hexamer. Here we experimentally probe the physical hexamer–hexamer interactions and the biological roles of the Lon dodecamer. Using structure prediction methods coupled with mutagenesis, we identified a key interface and specific residues within the Lon N domain that participates in an intermolecular coiled coil unique to the dodecamer. With this knowledge, we made a Lon variant (Lon^VQ) that forms a dodecamer with increased stability, as determined by analytical ultracentrifugation and electron microscopy. Using this altered Lon, we characterize the Lon dodecamer's activities using a panel of substrates. Lon dodecamers are clearly functional, and complement critical lon‐ phenotypes but also exhibit altered substrate specificity. For example, the small heat shock proteins IbpA and IbpB are only efficiently degraded well by the hexamer. Thus, by elucidating the intermolecular contacts connecting the hexamers, we are starting to illuminate how dodecamer formation versus disassembly can alter Lon function under conditions where controlling specific activities and substrate preferences of this key protease may be advantageous.     

Human cytomegalovirus US3 chimeras containing US2 cytosolic residues acquire major histocompatibility class I and II protein degradation properties

Human cytomegalovirus (HCMV) glycoprotein US2 increases the proteasome-mediated degradation of major histocompatibility complex (MHC) class I heavy chain (HC), class II DR-alpha and DM-alpha proteins, and HFE, a nonclassical MHC protein. US2-initiated degradation of MHC proteins apparently involves the recruitment of cellular proteins that participate in a process known as endoplasmic reticulum (ER)-associated degradation. ER-associated degradation is a normal process by which misfolded proteins are recognized and translocated into the cytoplasm for degradation by proteasomes. It has been demonstrated that truncated forms of US2, especially those lacking the cytoplasmic domain (CT), can bind MHC proteins but do not cause their degradation. To further assess how the US2 CT domain interacts with the cellular components of the ER-associated degradation pathway, we constructed chimeric proteins in which the US2 CT domain or the CT and transmembrane (TM) domains replaced those of the HCMV glycoprotein US3. US3 also binds both class I and II proteins but does not cause their degradation. Remarkably, chimeras containing the US2 CT domain caused the degradation of both MHC class I and II proteins although this degradation was less than that by wild-type US2. Therefore, the US2 CT and TM domains can confer on US3 the capacity to degrade MHC proteins. We also analyzed complexes containing MHC proteins and US2, US3, US11, or US3/US2 chimeras for the presence of cdc48/p97 ATPase, a protein that binds polyubiquitinated proteins and likely functions in the extraction of substrates from the ER membrane before the substrates meet proteasomes. p97 ATPase was present in immunoprecipitates containing US2, US11, and two chimeras that included the US2 CT domain, but not in US3 complexes. Therefore, it appears that the CT domain of US2 participates in recruiting p97 ATPase into ER-associated degradation complexes.     

The active site of a lon protease from Methanococcus jannaschii distinctly differs from the canonical catalytic Dyad of Lon proteases

ATP-dependent Lon proteases catalyze the degradation of various regulatory proteins and abnormal proteins within cells. Methanococcus jannaschii Lon (Mj-Lon) is a homologue of Escherichia coli Lon (Ec-Lon) but has two transmembrane helices within its N-terminal ATPase domain. We solved the crystal structure of the proteolytic domain of Mj-Lon using multiwavelength anomalous dispersion, refining it to 1.9-angstroms resolution. The structure displays an overall fold conserved in the proteolytic domain of Ec-Lon; however, the active site shows uniquely configured catalytic Ser-Lys-Asp residues that are not seen in Ec-Lon, which contains a catalytic dyad. In Mj-Lon, the C-terminal half of the beta4-alpha2 segment is an alpha-helix, whereas it is a beta-strand in Ec-Lon. Consequently, the configurations of the active sites differ due to the formation of a salt bridge between Asp-547 and Lys-593 in Mj-Lon. Moreover, unlike Ec-Lon, Mj-Lon has a buried cavity in the region of the active site containing three water molecules, one of which is hydrogen-bonded to catalytic Ser-550. The geometry and environment of the active site residues in Mj-Lon suggest that the charged Lys-593 assists in lowering the pK(a) of the Ser-550 hydroxyl group via its electrostatic potential, and the water in the cavity acts as a proton acceptor during catalysis. Extensive sequence alignment and comparison of the structures of the proteolytic domains clearly indicate that Lon proteases can be classified into two groups depending on active site configuration and the presence of DGPSA or (D/E)GDSA consensus sequences, as represented by Ec-Lon and Mj-Lon.     

Specific recognition of four-way DNA junctions by the C-terminal zinc-binding domain of HPV oncoprotein E6

E6 is an oncoprotein implicated in cervical cancers produced by " high risk " human papillomaviruses. E6 binds specifically to several cellular proteins, including the tumour suppressor p53 and the ubiquitin ligase E6-AP. However, E6 is also a DNA-binding protein which recognizes a structural motive present in four-way junctions. Here, we demonstrate that the C-terminal zinc-binding domain of E6, expressed separately from the rest of the protein, fully retains the selective four-way junction recognition activity. The domain can bind to two identical and independent sites on a single junction, whereas full-length E6 can only bind to one site. The junction bound to either one or two domains adopts an extended square conformation. These results allow us to assign the structure-dependent DNA recognition activity of E6 to its C-terminal domain, which therefore represents a new class of zinc-stabilized DNA-binding module. Comparison with the binding characteristics of other junction-specific proteins enlightens the rules which govern protein-induced deformation of four-way DNA junctions.     

Structure of the catalytic domain of the human mitochondrial Lon protease: Proposed relation of oligomer formation and activity

ATP‐dependent proteases are crucial for cellular homeostasis. By degrading short‐lived regulatory proteins, they play an important role in the control of many cellular pathways and, through the degradation of abnormally misfolded proteins, protect the cell from a buildup of aggregates. Disruption or disregulation of mammalian mitochondrial Lon protease leads to severe changes in the cell, linked with carcinogenesis, apoptosis, and necrosis. Here we present the structure of the proteolytic domain of human mitochondrial Lon at 2 Å resolution. The fold resembles those of the three previously determined Lon proteolytic domains from Escherichia coli, Methanococcus jannaschii, and Archaeoglobus fulgidus. There are six protomers in the asymmetric unit, four arranged as two dimers. The intersubunit interactions within the two dimers are similar to those between adjacent subunits of the hexameric ring of E. coli Lon, suggesting that the human Lon proteolytic domain also forms hexamers. The active site contains a 3₁₀ helix attached to the N‐terminal end of α‐helix 2, which leads to the insertion of Asp852 into the active site, as seen in M. jannaschii. Structural considerations make it likely that this conformation is proteolytically inactive. When comparing the intersubunit interactions of human with those of E. coli Lon taken with biochemical data leads us to propose a mechanism relating the formation of Lon oligomers with a conformational shift in the active site region coupled to a movement of a loop in the oligomer interface, converting the proteolytically inactive form seen here to the active one in the E. coli hexamer.