Roles of the N domain of the AAA+ Lon protease in substrate recognition,allosteric regulation and chaperone activity

Degron binding regulates the activities of the AAA+ Lon protease in addition to targeting proteins for degradation. The sul20 degron from the cell‐division inhibitor SulA is shown here to bind to the N domain of Escherichia coli Lon, and the recognition site is identified by cross‐linking and scanning for mutations that prevent sul20‐peptide binding. These N‐domain mutations limit the rates of proteolysis of model sul20‐tagged substrates and ATP hydrolysis by an allosteric mechanism. Lon inactivation of SulA in vivo requires binding to the N domain and robust ATP hydrolysis but does not require degradation or translocation into the proteolytic chamber. Lon‐mediated relief of proteotoxic stress and protein aggregation in vivo can also occur without degradation but is not dependent on robust ATP hydrolysis. In combination, these results demonstrate that Lon can function as a protease or a chaperone and reveal that some of its ATP‐dependent biological activities do not require translocation.     

Overproduction and purification of Lon protease fromEscherichia coli using a maltose-binding protein fusion system

Lon protease, which plays a major role in degradation of abnormal proteins inEscherichia coli, was overproduced and efficiently purified using the maltose-binding protein (MBP) fusion vector. The MBP-Lon fusion protein was expressed in a soluble form inE. coli and purified to homogeneity by amylose resin in a single step. Lon protease was split from MBP by cleaving a fusion point between MBP and Lon with factor Xa and purified by amylose resin and subsequent gel filtration. In this simple method, Lon protease was purified to homogeneity. Purified MBP-Lon fusion protein and Lon protease showed similar breakdown activities with a peptide (succinyl-l-phenylalanyl-l-leucyl-phenylalanyl--d-methoxynaphthylamide) and protein (-casein) in the presence of ATP. Therefore, the gene-fusion approach described in this study is useful for the production of functional Lon protease. MBP-Lon fusion protein, which both binds to the amylose resin and has ATP-dependent protease activity, should be especially valuable for its application in the degradation of abnormal proteins by immobilized enzymes.     

Functional dissection of a cell-division inhibitor, SulA, of Escherichia coli and its negative regulation by Lon

SulA is induced in Escherichia coli by the SOS response and inhibits cell division through interaction with FtsZ. To determine which region of SulA is essential for the inhibition of cell division, we constructed a series of N-terminal and C-terminal deletions of SulA and a series of alanine substitution mutants. Arginine at position 62, leucine at 67, tryptophan at 77 and lysine at 87, in the central region of SulA, were all essential for the inhibitory activity. Residues 3–27 and the C-terminal 21 residues were dispensable for the activity. The mutant protein lacking N-terminal residues 3–47 was inactive, as was that lacking the C-terminal 34 residues. C-terminal deletions of 8 and 21 residues increased the growth-inhibiting activity in lon ⁺ cells, but not in lon ⁻ cells. The wild-type and mutant SulA proteins were isolated in a form fused to E. coli maltose-binding protein, and tested in vitro for sensitivity to Lon protease. Lon degraded wild-type SulA and a deletion mutant lacking the N-terminal 93 amino acids, but did not degrade the derivative lacking 21 residues at the C-terminus. Futhermore, the wild-type SulA and the N-terminal deletion mutant formed a stable complex with Lon, while the C-terminal deletion did not. MBP fused to the C-terminal 20 residues of SulA formed a stable complex with, but was not degraded by Lon. When LacZ protein was fused at its C-terminus to 8 or 20 amino acid residues from the C-terminal region of SulA the protein was stable in lon ⁺ cells. These results indicate that the C-terminal 20 residues of SulA permit recognition by, and complex formation with, Lon, and are necessary, but not sufficient, for degradation by Lon. Received: 8 October 1996 / Accepted: 27 November 1996     

A Mutation in the N Domain of Escherichia coli Lon Stabilizes Dodecamers and Selectively Alters Degradation of Model Substrates

Escherichia coli Lon, an ATP-dependent AAA⁺ protease, recognizes and degrades many different substrates, including the RcsA and SulA regulatory proteins. More than a decade ago, the E240K mutation in the N domain of Lon was shown to prevent degradation of RcsA but not SulA in vivo. Here, we characterize the biochemical properties of the E240K mutant in vitro and present evidence that the effects of this mutation are complex. For example, Lon^E240K exists almost exclusively as a dodecamer, whereas wild-type Lon equilibrates between hexamers and dodecamers. Moreover, Lon^E240K displays degradation defects in vitro that do not correlate in any simple fashion with degron identity, substrate stability, or dodecamer formation. The Lon sequence segment near residue 240 is known to undergo nucleotide-dependent conformational changes, and our results suggest that this region may be important for coupling substrate binding with allosteric activation of Lon protease and ATPase activity.     

Regulatory role of C-terminal residues of SulA in its degradation by Lon protease in Escherichia coli

The SulA protein is a cell division inhibitor in Escherichia coli, and is specifically degraded by Lon protease. To study the recognition site of SulA for Lon, we prepared a mutant SulA protein lacking the C-terminal 8 amino acid residues (SA8). This deletion protein was accumulated and stabilized more than native SulA in lon(+) cells in vivo. Moreover, the deletion SulA fused to maltose binding protein was not degraded by Lon protease, and did not stimulate the ATPase or peptidase activity of Lon in vitro, probably due to the much reduced interaction with Lon. A BIAcore study showed that SA8 directly interacts with Lon. These results suggest that SA8 of SulA was recognized by Lon protease. The SA8 peptide, KIHSNLYH, specifically inhibited the degradation of native SulA by Lon protease in vitro, but not that of casein. A mutant SA8, KAHSNLYH, KIASNLYH, or KIHSNAYH, also inhibited the degradation of SulA, while such peptides as KIHSNLYA did not. These results show that SulA has the specified rows of C-terminal 8 residues recognized by Lon, leading to facilitated binding and subsequent cleavage by Lon protease both in vivo and in vitro.     

Functional dissection of a cell-division inhibitor, SulA, of Escherichia coli and its negative regulation by Lon

SulA is induced in Escherichia coli by the SOS response and inhibits cell division through interaction with FtsZ. To determine which region of SulA is essential for the inhibition of cell division, we constructed a series of N-terminal and C-terminal deletions of SulA and a series of alanine substitution mutants. Arginine at position 62, leucine at 67, tryptophan at 77 and lysine at 87, in the central region of SulA, were all essential for the inhibitory activity. Residues 3–27 and the C-terminal 21 residues were dispensable for the activity. The mutant protein lacking N-terminal residues 3–47 was inactive, as was that lacking the C-terminal 34 residues. C-terminal deletions of 8 and 21 residues increased the growth-inhibiting activity in lon ⁺ cells, but not in lon ^? cells. The wild-type and mutant SulA proteins were isolated in a form fused to E. coli maltose-binding protein, and tested in vitro for sensitivity to Lon protease. Lon degraded wild-type SulA and a deletion mutant lacking the N-terminal 93 amino acids, but did not degrade the derivative lacking 21 residues at the C-terminus. Futhermore, the wild-type SulA and the N-terminal deletion mutant formed a stable complex with Lon, while the C-terminal deletion did not. MBP fused to the C-terminal 20 residues of SulA formed a stable complex with, but was not degraded by Lon. When LacZ protein was fused at its C-terminus to 8 or 20 amino acid residues from the C-terminal region of SulA the protein was stable in lon ⁺ cells. These results indicate that the C-terminal 20 residues of SulA permit recognition by, and complex formation with, Lon, and are necessary, but not sufficient, for degradation by Lon.     

ATP-dependent degradation of SulA, a cell division inhibitor, by the HslVU protease in Escherichia coli.

HslVU is an ATP-dependent protease consisting of two multimeric components, the HslU ATPase and the HslV peptidase. To gain an insight into the role of HslVU in regulation of cell division, the reconstituted enzyme was incubated with SulA, an inhibitor of cell division in Escherichia coli, or its fusion protein with maltose binding protein (MBP). HslVU degraded both proteins upon incubation with ATP but not with its nonhydrolyzable analog, ATPgammaS, indicating that the degradation of SulA requires ATP hydrolysis. The pulse-chase experiment using an antibody raised against MBP-SulA revealed that the stability of SulA increased in hsl mutants and further increased in lon/hsl double mutants, indicating that SulA is an in vivo substrate of HslVU as well as of protease La (Lon). These results suggest that HslVU in addition to Lon plays an important role in regulation of cell division through degradation of SulA.     

Protein substrates and heat shock reduce the DNA-binding ability of Escherichia coli Lon protease

Interaction between the fusion protein MBP-Lon, formed by maltose-binding protein and Lon protease, and the plasmid pBR322 was studied to clarify the DNA-binding behavior of the Lon protease. Since the MBP-Lon fusion protein that was bound to the plasmid was strongly adsorbed by amylose resin, complex formation and dissociation were determined by quantifying the unadsorbed plasmid using agarose gel electrophoresis. The autolysis of MBP-Lon fusion protein was suppressed when the protein was bound to the plasmid. The plasmid was completely dissociated from MBP-Lon fusion protein by the addition of the protein substrates of Lon protease (i.e. -casein and denatured bovine serum albumin). In addition, at high temperatures, MBP-Lon fusion protein lost its plasmid-binding ability, although it fully retained ATP-dependent protease activity. These results suggest that Lon protease loses DNA-binding ability when cells are exposed to abnormal conditions and the amount of damaged proteins increases. On the other hand, DNA probably plays an important role in controlling the Lon protease activity in cells under normal conditions by entrapping the enzyme.     

A conserved domain in Escherichia coli Lon protease is involved in substrate discriminator activity

Lon protease of Escherichia coli regulates a diverse set of physiological responses including cell division, capsule production, plasmid stability, and phage replication. Little is known about the mechanism of substrate recognition by Lon. To examine the interaction of Lon with two of its substrates, RcsA and SulA, we generated point mutations in lon which affected its substrate specificity. The most informative lon mutant overproduced capsular polysaccharide (RcsA stabilized) yet was resistant to DNA-damaging agents (SulA degraded). Immunoblots revealed that RcsA protein persisted in this mutant whereas SulA protein was rapidly degraded. The mutant contains a single-base change within lon leading to a single amino acid change of glutamate 240 to lysine. E240 is conserved among all Lon isolates and resides in a charged domain that has a high probability of adopting a coiled-coil conformation. This conformation, implicated in mediating protein-protein interactions, appears to confer substrate discriminator activity on Lon. We propose a model suggesting that this coiled-coil domain represents the discriminator site of Lon.     

Saturation and specificity of the Lon protease of Escherichia coli.

Lon is an ATP-dependent protease of Escherichia coli. The lon mutation has a pleiotropic phenotype: UV sensitivity, mucoidy, deficiency for lysogenization by bacteriophage lambda and P1, and lower efficiency in the degradation of abnormal proteins. All of these phenotypes are correlated with the loss of protease activity. Here we examine the effects of overproduction of one Lon substrate, SulA, and show that it protects two other substrates from degradation. To better understand this protection, we mutagenized the sulA gene and selected for mutants that have partially or totally lost their ability to saturate the Lon protease and thus can no longer protect another substrate. Some of the SulA mutants lost their ability to protect RcsA from degradation but could still protect the O thermosensitive mutant protein (Ots). All of the mutants retained their capacity to induce cell division inhibition. It was also found that deletion of the C-terminal end of SulA affected its activity but did not affect its susceptibility to Lon. We propose that Lon may have more than one specificity for peptide cleavage.     

Molecular Cloning and Expression of a cDNA Encoding Lon Protease from rice (Oryza sativa)

The ATP-dependent Lon protease is a highly conserved enzyme that is present in archeae, eubacteria, and eukaryotes, and plays an important role in intracellular protein degradation. We have isolated a Lon protease gene, OsLon1, from Oryza sativa. The cDNA contained a 2,655 bp ORF. Comparative analysis showed that OsLon1 shared significant similarity with the previously reported Lon proteases from maize, Arabidopsis, human, and bacteria. Tissue expression pattern analysis revealed that OsLon1 was highly expressed in young leaves, mature leaves, and leaf sheaths but only weakly in young roots, mature roots, and young panicles. The OsLon1 gene was successfully expressed in E. coli and the detected protein size, about 120 kDa, matched the expected molecular mass of the His-tagged OsLon1 protein.     

Proteolysis and synthetic strategy of human G-CSF in Escherichia coli BL21(DE3)

We report for the first time that the C-terminal region of hG-CSF suffers from proteolytic degradation when human granulocyte colony-stimulating factor (hG-CSF) is directly expressed in Escherichia coli BL21(DE3). It is believed that the rapid proteolysis occurs at the C-terminus of hG-CSF that is very easily exposed to E. coli protease(s) during a short period following protein synthesis and prior to completion of the formation of the inclusion body. The recombinant hG-CSF that is expressed with an N-terminal fusion partner is effectively protected from the proteolysis. It seems that since the N-terminus of hG-CSF is located very close to the C-terminus, the presence of the N-terminal fusion partner masks the C-terminal region of hG-CSF and protects it from proteolytic degradation by E. coli protease(s). Furthermore, the solubility of hG-CSF markedly increased in E. coli cytoplasm when a stress-responsive and aggregation-resistant protein, i.e. aspartate carbamoyl-transferase catalytic chain (PyrB) was used as a novel N-terminal fusion partner proteins.     

Co‐evolution of multipartite interactions between an extended tmRNA tag and a robust Lon protease in Mycoplasma

Messenger RNAs that lack in‐frame stop codons promote ribosome stalling and accumulation of aberrant and potentially harmful polypeptides. The SmpB‐tmRNA quality control system has evolved to solve problems associated with non‐stop mRNAs, by rescuing stalled ribosomes and directing the addition of a peptide tag to the C‐termini of the associated proteins, marking them for proteolysis. In Escherichia coli, the ClpXP system is the major contributor to disposal of tmRNA‐tagged proteins. We have shown that the AAA+ Lon protease can also degrade tmRNA‐tagged proteins, but with much lower efficiency. Here, we present a unique case of enhanced recognition and degradation of an extended Mycoplasma pneumoniae (MP) tmRNA tag by the MP‐Lon protease. We demonstrate that MP‐Lon can efficiently and selectively degrade MP‐tmRNA‐tagged proteins. Most significantly, our studies reveal that the larger (27 amino acids long) MP‐tmRNA tag contains multiple discrete signalling motifs for efficient recognition and rapid degradation by Lon. We propose that higher‐affinity multipartite interactions between MP‐Lon and the extended MP‐tmRNA tag have co‐evolved from pre‐existing weaker interactions, as exhibited by Lon in E. coli, to better fulfil the function of MP‐Lon as the sole soluble cytoplasmic protease responsible for the degradation of tmRNA‐tagged proteins.     

Biosynthesis of Inositol by an Enzyme System in the Rice Seeds

As the first step for production of human apolipoprotein E (hApoE) in Saccharomyces cerevisiae, the hApoE cDNA was cloned in Escherichia coli, on the basis of the nucleotide sequence reported previously. When the hApoE cDNA including its pre-sequence-encoding region was expressed under the control of the GAL7 promoter, no protein immunoreactive with anti-hApoE antibody was detected either in the culture medium or inside the cells. For efficient production and secretion of hApoE in S. cerevisiae, the mature hApoE-encoding region was fused to the prepro-sequence region of Rhizomucor rennin (MPR) and to the whole MPR gene including its prepro- and mature-MPR regions. When the fusion gene consisting of the prepro-sequence-encoding region and hApoE regions was expressed in S. cerevisiae, no protein reactive with the anti-hApoE antibody was detected in any fraction of the yeast cells, probably due to rapid degradation of the hApoE protein by yeast proteases. On the othe hand, when hApoE was expressed as a fusion to the whole MPR protein, a considerable amount of the fused protein was secreted into the medium. The preprosequence of MPR was correctly processed from the fused protein in the medium by autocatalytic activity of MPR and by a protease(s) of the host cell. Integration of the fusion gene into the chromosome at a copy number of eight led to secretion of the fused protein in a larger amount than the case when the fusion gene was carried on a 2-µm plasmid with its copy number of a few hundreds, because the 2-µm derived plasmid containing the fusion gene was very unstable in the yeast cells. The secretion level was also improved by changing g the culture conditions. A maximum yield of hApoE part in the secreted fused protein was estimated to be 23.7 mg per liter and the amount of the fused protein was calculated to be 53.0 mg per liter.     

Coupling of Proteolysis to ATP Hydrolysis upon Escherichia coliLon Protease Functioning: II. Hydrolysis of ATP and Activity of the Enzyme Peptide Hydrolase Sites

The absence of direct correlation between the efficiency of functioning of ATPase and peptide hydrolase sites of Lon protease was revealed. It was shown that Lon protease is an allosteric enzyme, in which the catalytic activity of peptide hydrolase sites is provided by the binding of nucleotides, their magnesium complexes, and free magnesium ions in the enzyme ATPase sites. It was revealed that the ADP–Mg complex, an inhibitor of the native enzyme, is an activator of the Lon-K362Q (the Lon protease mutant in the ATPase site). Variants of functional contacts between different sites of the enzyme are considered. It was established that two ways of signal transduction from the ATPase sites to peptide hydrolase ones exist in the Lon protease oligomer--intra- and intersubunit ways. The enzyme ATPase sites are suggested to be located in the areas of the complementary surfaces of subunits. It is hypothesized that upon degradation of protein substrates by the E. coliLon protease in vivoATP hydrolysis acts as a factor of limitation of the enzyme degrading activity.     

Effects of disruption of heat shock genes on susceptibility of Escherichia coli to fluoroquinolones

Background

It is well known that expression of certain bacterial genes responds rapidly to such stimuli as exposure to toxic chemicals and physical agents. It is generally believed that the proteins encoded in these genes are important for successful survival of the organism under the hostile conditions. Analogously, the proteins induced in bacterial cells exposed to antibiotics are believed to affect the organisms' susceptibility to these agents.

Results

We demonstrated that Escherichia coli cells exposed to levofloxacin (LVFX), a fluoroquinolone (FQ), induce the syntheses of heat shock proteins and RecA. To examine whether the heat shock proteins affect the bactericidal action of FQs, we constructed E. coli strains with mutations in various heat shock genes and tested their susceptibility to FQs. Mutations in dnaK, groEL, and lon increased this susceptibility; the lon mutant exhibited the greatest effects. The increased susceptibility of the lon mutant was corroborated by experiments in which the gene encoding the cell division inhibitor, SulA, was subsequently disrupted. SulA is induced by the SOS response and degraded by the Lon protease. The findings suggest that the hypersusceptibility of the lon mutant to FQs could be due to abnormally high levels of SulA protein resulting from the depletion of Lon and the continuous induction of the SOS response in the presence of FQs.

Conclusion

The present results show that the bactericidal action of FQs is moderately affected by the DnaK and GroEL chaperones and strongly affected by the Lon protease. FQs have contributed successfully to the treatment of various bacterial infections, but their widespread use and often misuse, coupled with emerging resistance, have gradually compromised their utility. Our results suggest that agents capable of inhibiting the Lon protease have potential for combination therapy with FQs.     

Somatic homologous recombination in planta: The recombination frequency is dependent on the allelic state of recombining sequences and may be influenced by genomic position effects

The Escherichia coli sodA gene encoding the antioxidant enzyme Mn-containing superoxide dismutase (MnSOD), was cloned in the expression vector pMG36e. This vector has a multiple cloning site down-stream of a promoter and Shine-Dalgarno sequences derived from Lactococcus. The protein-coding region of sodA from E. coli was amplified by the polymerase chain reaction, using a thermocycler and Taq DNA polymerase before cloning into pMG36e. When introduced into E. coli, the recombinant plasmid expressed the predicted fusion protein, both in the presence and absence of oxygen. The expression of the fusion protein in E. coli was verified by SOD assays, activity gels and Western blots. The recombinant plasmid was also introduced into Lactococcus lactis, which contains a resident SOD, and into Lactobacillus gasseri, which is devoid of SOD. Transformed lactococci expressed an active SodA fusion protein plus an active hybrid protein composed of subunits of the Lactococcus and the recombinant E. coli enzymes. Transformants of L. gasseri expressed only the fusion SodA protein, which was enzymatically active.     

The unique sites in SulA protein preferentially cleaved by ATP-dependent Lon protease from Escherichia coli.

SulA protein is known to be one of the physiological substrates of Lon protease, an ATP-dependent protease from Escherichia coli. In this study, we investigated the cleavage specificity of Lon protease toward SulA protein. The enzyme was shown to cleave approximately 27 peptide bonds in the presence of ATP. Among them, six peptide bonds were cleaved preferentially in the early stage of digestion, which represented an apparently unique cleavage sites with mainly Leu and Ser residues at the P1, and P1' positions, respectively, and one or two Gln residues in positions P2-P5. They were located in the central region and partly in the C-terminal region, both of which are known to be important for the function of SulA, such as inhibition of cell growth and interaction with Lon protease, respectively. The other cleavage sites did not represent such consensus sequences, though hydrophobic or noncharged residues appeared to be relatively preferred at the P1 sites. On the other hand, the cleavage in the absence of ATP was very much slower, especially in the central region, than in the presence of ATP. The central region was predicted to be rich in alpha helix and beta sheet structures, suggesting that the enzyme required ATP for disrupting such structures prior to cleavage. Taken together, SulA is thought to contain such unique cleavage sites in its functionally and structurally important regions whose preferential cleavage accelerates the ATP-dependent degradation of the protein by Lon protease.