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.     

Overproduction and purification of SulA fusion protein in Escherichia coli and its degradation by Lon protease in vitro

To overproduce extremely unstable SulA protein, which is the cell-division inhibitor of Escherichia coli, we fused the sulA gene to the maltose-binding protein (MBP) fusion vectors with or without the signal sequence (plasmids pMAL-p-SulA and pMAL-c-SulA respectively). The amount of the full-length fusion protein expressed from the plasmid pMAL-p-SulA (pre-MBP-SulA) in E. coli was much larger than that expressed from the plasmid pMAL-c-SulA (MBP-SulA). A major amount of the pre-MBP-SulA fusion protein was expressed in a soluble form and affinity-purified by amylose resin. Since site-specific cleavage of the fusion protein with factor Xa resulted in the precipitation of SulA protein, the pre-MBP-SulA fusion protein was used to study the degradation of SulA protein by E. coli Lon protease in vitro. It was found that only the SulA portion of the fusion protein was degraded by Lon protease in an ATP-dependent manner. This result provides direct evidence that Lon protease plays an important role in the rapid degradation of SulA protein in cells.     

ATP依赖的人Lon蛋白酶的表达、纯化及其活性鉴定

ATP依赖的人Lon蛋白酶是一种同质寡聚、环状的蛋白酶,主要位于细胞线粒体基质中。许多研究表明,Lon蛋白酶对于维护细胞的内环境稳定起着重要作用,并参与线粒体蛋白质量控制和代谢调控。将pPROEX1 His6-Lon重组质粒在Escherichia coli Rosetta 2菌株中诱导表达用Ni2＋柱亲和层析法纯化,获得纯度较高的目的蛋白。经纯化后,Lon蛋白酶的比酶活达到0.17 U/mg。通过多肽底物Rhodamine 110、bis-（CBZ-L-alanyl-L-alanine amide）[（Z-AA）2 Rh110]的降解检测显示,Lon蛋白酶具有肽酶活性,并被ATP所刺激。Casein和线粒体转录因子A降解实验表明,纯化的Lon蛋白酶具有蛋白水解活性,而且蛋白水解活性依赖于ATP。     

Regulatory role of cardiolipin in the activity of an ATP-dependent protease, Lon, from Escherichia coli

Lon is an ATP-dependent serine protease that plays a significant role in the quality control of proteins in cells, degrading misfolded proteins and certain short-lived regulatory proteins under stresses as such heat-shock and UV irradiation. It is known that some polymers containing phosphate groups regulate enzymatic activity by binding with Lon. We focused on the phospholipids of biological membrane components such as phosphatidylethanolamine, phosphatidylcholine, phosphatidylglycerol and cardiolipin (CL), and examined whether or not liposomes containing these phospholipids regulate the enzymatic activity of Lon. CL-containing liposomes specifically inhibited both the proteolytic and ATPase activities of Lon in a dose-dependent manner. In addition, on pull-down assay, we found that CL-containing liposomes selectively bound to Lon. The interaction between CL-containing liposomes and Lon changed with the order of addition of Mg(2+)/ATP. When CL-containing liposomes were added after the addition of Mg(2+)/ATP to Lon, the binding of CL-containing liposomes to Lon was significantly decreased as compared with the reversed order. In fact, we found that CL-containing liposomes bound to Lon, resulting in inhibition of the enzymatic activity of Lon. These results suggest that Lon interacts with CL in biological membranes, which may regulate the functions of Lon as a protein-degrading centre in accordance with environmental changes inside cells.     

Hyperproduction of a recombinant fusion protein of Staphylococcus aureus V8 protease in Escherichia coli and its processing by OmpT protease to release an active V8 protease derivative

The expression of a recombinant fusion protein including Staphylococcus aureus V8 protease was studied by using Escherichia coli as the host strain. When the mature V8 protease was expressed as a fusion protein with a truncated E. coli \-galactosidase (\-gal97S4D), we could not obtain a sufficient amount of the enzyme because of the toxicity resulting from the expressed protease activity. Synthesis of V8 protease was increased by constructing a sandwich-type fusion protein consisting of \-gal197S4D, a V8 protease derivative with the 56 C-terminal amino acids deleted (V856) and a truncated aminoglycoside-3'-phosphotransferase. This fusion protein was successfully produced as inactive inclusion bodies. To release the V856 protease from the fusion protein, we developed a novel processing method using an endogeneous E. coli OmpT protease, which can recognize the dibasic amino acid residues located in the linker peptides of the fusion protein. After solubilizing the inclusion bodies with urea, the V856 protein was automatically released from the fusion protein by the OmpT protease, which was coprecipitated with the inclusion bodies. The V856 protease thus obtained showed the same enzymatic activity as that of the native V8 protease. We demonstrate in this study that the N-terminal prepro sequence and the C-terminal repeated sequence of this enzyme are not necessary for its enzymatic activity and protein folding.     

Identification of a gene encoding Lon protease from Brevibacillus thermoruber WR-249 and biochemical characterization of its thermostable recombinant enzyme.

A gene encoding thermostable Lon protease from Brevibacillus thermoruber WR-249 was cloned and characterized. The Br. thermoruber Lon gene (Bt-lon) encodes an 88 kDa protein characterized by an N-terminal domain, a central ATPase domain which includes an SSD (sensor- and substrate-discrimination) domain, and a C-terminal protease domain. The Bt-lon is a heat-inducible gene and may be controlled under a putative Bacillus subtilis sigmaA-dependent promoter, but in the absence of CIRCE (controlling inverted repeat of chaperone expression). Bt-lon was expressed in Escherichia coli, and its protein product was purified. The native recombinant Br. thermoruber Lon protease (Bt-Lon) displayed a hexameric structure. The optimal temperature of ATPase activity for Bt-Lon was 70 degrees C, and the optimal temperature of peptidase and DNA-binding activities was 50 degrees C. This implies that the functions of Lon protease in thermophilic bacteria may be switched, depending on temperature, to regulate their physiological needs. The peptidase activity of Bt-Lon increases substantially in the presence of ATP. Furthermore, the substrate specificity of Bt-Lon is different from that of E. coli Lon in using fluorogenic peptides as substrates. Notably, the Bt-Lon protein shows chaperone-like activity by preventing aggregation of denatured insulin B-chain in a dose-dependent and ATP-independent manner. In thermal denaturation experiments, Bt-Lon was found to display an indicator of thermostability value, Tm of 71.5 degrees C. Sequence comparison with mesophilic Lon proteases shows differences in the rigidity, electrostatic interactions, and hydrogen bonding of Bt-Lon relevant to thermostability.     

Proteolysis Coupled to ATP Hydrolysis: Regulation of the Activity of Proteolytic Sites of Lon Protease from Escherichia coli

Regulation of activity of the proteolytic sites of Lon protease was studied. It was found that ATP–Mg has the properties of a noncompetitive activator of peptidase sites. The processive mechanism of the hydrolysis of protein substrates by Lon protease was experimentally confirmed under the conditions of ATP hydrolysis. It was shown that the oligomeric state of the enzyme is the necessary prerequisite for the processive proteolysis by native Lon protease. The study of the properties of the mixed mutant Lon-K362Q/S679A confirmed the existence of intra- and intersubunit pathways of signal transduction from the ATPase to proteolytic sites. The mutual influence of substrates of Lon protease was studied, and the existence of cooperative interactions between the peptidase sites in the oligomeric enzyme was suggested.     

Mitochondrial Lon regulates apoptosis through the association with Hsp60–mtHsp70 complex

Human Lon protease is a mitochondrial matrix protein with several functions, including protein degradation, mitochondrial DNA (mtDNA) binding, and chaperone activity. Lon is currently emerging as an important regulator of mitochondria-contributed tumorigenesis due to its overexpression in cancer cells. To understand the mechanism of increased Lon in tumor cells, we studied the interactome to identify the chaperone Lon-associated proteins by proteomics approaches using the cells overexpressing Lon. In the present study, we designed a method connecting co-immunoprecipitation (Co-IP) to in-solution digestion for the shotgun mass spectrometry. We identified 76 proteins that were putative Lon-associated proteins that participated in mitochondrial chaperone system, cellular metabolism and energy, cell death and survival, and mtDNA stability. The association between Lon and NDUFS8 or Hsp60–mtHsp70 complex was confirmed by Co-IP and immunofluorescence co-localization assay. We then found that the protein stability/level of Hsp60–mtHsp70 complex depends on the level of Lon under oxidative stress. Most importantly, the ability of increased Lon-inhibited apoptosis is dependent on Hsp60 that binds p53 to inhibit apoptosis. These results suggest that the mechanism underlying cell survival regulated by Lon is mediated by the maintenance of the protein stability of Hsp60–mtHsp70 complex. This new knowledge of chaperone Lon interactome will allow us to better understand the cellular mechanism of Lon in mitochondrial function and of its overexpression in enhancing cell survival and tumorigenesis.Under stress circumstances, proteins are at risk of being inactivated by misfolding, unfolding, or aggregation. Protein quality control (PQC) system, chaperones and proteases, safeguards the function under cellular stress conditions. The coordinated function of the two components is required to stabilize misfolded proteins and refold or remove them to avoid the deleterious effects of protein aggregation.^{1, 2}Lon is a highly conserved AAA+ (ATPases associated with a variety of cellular activities) protease and is committed to several crucial functions, including adenosine-5′-triphosphate (ATP)-dependent proteolytic, DNA binding, and chaperone-like activity.^{3, 4, 5} Eukaryotic Lon protease operates in PQC in mitochondria by its multiple functions^{4, 6, 7} and has a critical role in the maintenance of mitochondrial function, biogenesis, and homeostasis.⁸ Mitochondria orchestrate the process of cell life and death, thereby employing a decisive control over signaling leading to cellular survival, in particular the intrinsic pathway of apoptosis.⁹ Thus it is not surprising that the level of Lon regulates mitochondrial functions that contribute to cell fate and survival. Indeed, Lon downregulation leads to loss of mitochondrial function, early embryonic lethality, reduced cell proliferation, and apoptosis.^{10, 11, 12, 13} Lon upregulation is critical for cancer cell survival and tumorigenesis by regulating stress responses induced by oxidative condition.^{11, 12} Lon is a stress protein and induced by a number of stresses such as hypoxia and oxidative and mitochondrial unfolded protein stress,^{11, 14, 15, 16, 17} which are common stress phenotypes of cancer cells. During hypoxia, Lon is upregulated by the hypoxia-inducible factor-1α and is involved in a mechanism to respond to low oxygen availability and adapt cancer cells to a hypoxic environment.¹⁶ In addition to its proteolytic activity, Lon has been found to show chaperone properties.^{3, 11, 15} Lon promotes the assembly of cytochrome c oxidase (COX) 4–1 subunits, suggesting that Lon has chaperone activity in yeast and mammalian cells.^{15, 18} Molecular chaperones of heat-shock protein (HSP) family have important roles in promoting tumor growth and survival.^{19, 20} Thus mitochondrial Lon may be a protein chaperone to assist cells to survive and adapt to various stresses that are linked to oncogenesis. However, very few human Lon chaperone clients have been identified, and the mechanism of how upregulated Lon employs its chaperone activity to regulate apoptosis remains obscure.To study the roles of Lon overexpression in cancer cell survival, we utilized proteomic techniques to identify chaperone Lon-interacting proteins. The interactome suggests that Lon may participate in many cellular activities, including mitochondrial chaperones, cellular metabolism and energy, Redox regulation, cell death and survival, and mitochondrial DNA (mtDNA) stability. We identified heat-shock protein 60 (Hsp60), mtHsp70, and NDUFS8 (NADH dehydrogenase [ubiquinone] iron-sulfur protein 8) as Lon-interacting proteins by using co-immunoprecipitation (Co-IP) and immunofluorescence experiments. We further characterized that the protein stability of Hsp60 and mtHsp70 depends on the level of Lon under oxidative stress. We know the fact that Hsp60 and mtHsp70 forms a complex^{21, 22} and are overexpressed in cancer cells and have crucial roles in modulating the apoptotic pathways and in cancer development.¹⁹ Consistently, Hsp60 is essential to maintain apoptosis inhibition preserved by Lon overexpression. These results suggest that the mechanism underlying apoptosis regulated by Lon is mediated by the maintenance of the stability of Hsp60–mtHsp70 complex.     

Enhanced export of beta-galactosidase fusion proteins in prlF mutants is Lon dependent.

We have used fusions of the outer membrane protein LamB to beta-galactosidase (encoded by lacZ) to study the protein export process. This LamB-LacZ hybrid protein blocks export when synthesized at high levels, as evidenced by inducer (maltose) sensitivity, a phenomenon termed LacZ hybrid jamming. The prlF1 mutation relieves LacZ hybrid jamming and allows localization of the fusion protein to a noncytoplasmic compartment. prlF1 and similar alleles are gain-of-function mutations. Null mutations in this gene confer no obvious phenotypes. Extragenic suppressors of a gain-of-function prlF allele have been isolated in order to understand how this gene product affects the export process. The suppressors are all lon null mutations, and they are epistatic to all prlF phenotypes tested. Lon protease activity has been measured in prlF1 cells and shown to be increased. However, the synthesis of Lon is not increased in a prlF1 background, suggesting a previously unidentified mechanism of Lon activation. Further analysis reveals that prlF1 activates degradation of cytoplasmically localized precursors in a Lon protease-dependent manner. It is proposed that accumulation of precursors during conditions of hybrid protein jamming titrates an essential export component(s), possibly a chaperone. Increased Lon-dependent precursor degradation would free this component, thus allowing increased protein export under jamming conditions.     

lon gene product of Escherichia coli is a heat-shock protein

The product of the pleiotropic gene lon is a protein with protease activity and has been tentatively identified as protein H94.0 on the reference two-dimensional gel of Escherichia coli proteins. Purified Lon protease migrated with the prominent cellular protein H94.0 in E. coli K-12 strains. Peptide map patterns of Lon protease and H94.0 were identical. A mutant form of the protease had altered mobility during gel electrophoresis. An E. coli B/r strain that is known to be defective in Lon function contained no detectable H94.0 protein under normal growth conditions. Upon a shift to 42 degrees C, however, the Lon protease was induced to high levels in K-12 strains and a small amount of protein became detectable at the H94.0 location in strain B/r. Heat induction of Lon protease was dependent on the normal allele of the regulatory gene, htpR, establishing lon as a member of the high-temperature-production regulon of E. coli.     

Degradation in vitro of bacteriophage lambda N protein by Lon protease from Escherichia coli

Lon protease from Escherichia coli degraded lambda N protein in a reaction mixture consisting of the two homogeneous proteins, ATP, and MgCl2 in 50 mM Tris, Ph 8.0. Genetic and biochemical data had previously indicated that N protein is a substrate for Lon protease in vivo (Gottesman, S., Gottesman, M., Shaw, J. E., and Pearson, M. L. (1981) Cell 24, 225-233). Under conditions used for N protein degradation, several lambda and E. coli proteins, including native proteins, oxidatively modified proteins, and cloned fragments of native proteins, were not degraded by Lon protease. Degradation of N protein occurred with catalytic amounts of Lon protease and required the presence of ATP or an analog of ATP. This is the first demonstration of the selective degradation of a physiological substrate by Lon protease in vitro. The turnover number for N protein degradation was approximately 60 +/- 10 min-1 at pH 8.0 in 50 mM Tris/HCl, 25 mM MgCl2 and 4 mM ATP. By comparison the turnover number for oxidized insulin B chain was 20 min-1 under these conditions. Kinetic studies suggest that N protein (S0.5 = 13 +/- 5 microM) is intermediate between oxidized insulin B chain (S0.5 = 160 +/- 10 microM) and methylated casein (S0.5 = 2.5 +/- 1 microM) in affinity for Lon protease. N protein was extensively degraded by Lon protease with an average of approximately six bonds cleaved per molecule. In N protein, as well as in oxidized insulin B chain and glucagon, Lon protease preferentially cut at bonds at which the carboxy group was contributed by an amino acid with an aliphatic side chain (leucine or alanine). However, not all such bonds of the substrates were cleaved, indicating that sequence or conformational determinants beyond the cleavage site affect the ability of Lon protease to degrade a protein.     

Effects of inorganic polyphosphate on the proteolytic and DNA-binding activities of Lon in Escherichia coli

Lon belongs to a unique group of proteases that bind to DNA and is involved in the regulation of several important cellular functions, including adaptation to nutritional downshift. Previously, we revealed that inorganic polyphosphate (polyP) increases in Escherichia coli in response to amino acid starvation and that it stimulates the degradation of free ribosomal proteins by Lon. In this work, we examined the effects of polyP on the proteolytic and DNA-binding activities of Lon. An order-of-addition experiment suggested that polyP first binds to Lon, which stimulates Lon-mediated degradation of ribosomal proteins. A polyP-binding assay using Lon deletion mutants showed that the polyP-binding site of Lon is localized in the ATPase domain. Because the same ATPase domain also contains the DNA-binding site, polyP can compete with DNA for binding to Lon. In fact, an equimolar amount of polyP almost completely inhibited DNA-Lon complex formation, suggesting that Lon binds to polyP with a higher affinity than it binds to DNA. Collectively, our results showed that polyP may control the cellular activity of Lon not only as a protease but also as a DNA-binding protein.     

Optimization of growth conditions for the production of proteolytically-sensitive proteins in the periplasmic space of Escherichia coli

Summary The expression of many secreted recombinant proteins in Gram-negative bacteria is limited by degradation in the periplasmic space. We have previously shown that the production of protein A--lactamase, a secreted fusion protein highly sensitive to proteolysis in Escherichia coli, can be increased in mutant strains deficient in up to three cell-envelope-associated proteolytic activities. In this work we investigated the effect of fermentation conditions on suppressing any residual proteolytic activity in various protease-deficient strains. Optimal production of the fusion protein was observed in cells grown under mildly acidic conditions (5.5pH6.0) and at low temperatures. These conditios were shown to specifically decrease the rate of proteolysis. In addition, a further increase in production was observed in cultures supplemented with 0.5 to 0.75 mM zinc chloride. This may relate to the inhibition of a cell envelope protease by Zn²⁺ ions. Offsprint requests to: G. Georgiou     

Backbone resonance assignments of the α sub-domain of Brevibacillus thermoruber Lon protease

Lon is an ATPases associated with diverse cellular activities protease and belongs to a unique group that binds DNA. The α sub-domain of Lon protease is responsible for DNA-binding, but the structural information for its DNA-recognition mode is still limited. Here, we report ¹H, ¹⁵N and ¹³C backbone assignment for the α sub-domain from Brevibacillus thermoruber Lon protease as the basis for the elucidation of its structure and interactions with DNA, necessary for understanding the allosteric regulatory mechanism of the enzymatic function.     

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.     

Enhanced mitochondrial biogenesis is associated with increased expression of the mitochondrial ATP-dependent Lon protease

Rats bearing the Zajdela hepatoma tumor and T3-treated hypothyroid rats were used to study the role of protein degradation in the process of mitochondrial biogenesis. It was shown that the activity, protein and mRNA levels of the ATP-dependent Lon protease increased in rapidly growing Zajdela hepatoma cells. The increase in the rate of mitochondrial biogenesis by thyroid hormone was similarly accompanied by enhanced expression of the Lon protease. The results imply that mitochondrial biogenesis in mammalian cells is, at least partially, regulated by the matrix Lon protease.     

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.     

Proteolysis coupled with ATP. Regulation of activity of proteolytic centers of Escherichia coli lon protease

Regulation of activity of the proteolytic sites of Lon protease was studied. It was found that ATP-Mg has the properties of a noncompetitive activator of peptidase sites. The processive mechanism of the hydrolysis of protein substrates by Lon protease was experimentally confirmed under the conditions of ATP hydrolysis. It was shown that the oligomeric state of the enzyme is the necessary prerequisite for the processive proteolysis by the native Lon protease. The study of the properties of the mixed mutant Lon-K362Q/S679A confirmed the existence of the intra- and intersubunit pathways of signal transduction from the ATPase to proteolytic sites. The mutual influence of substrates of Lon protease was studied, and the existence of cooperative interactions between the peptidase sites in the oligomeric enzyme was suggested.