Control of methionine biosynthesis in Escherichia coli by proteolysis

Most bacterial proteins are stable, with half-lives considerably longer than the generation time. In Escherichia coli, the few exceptions are unstable regulatory proteins. The results presented here indicate that the first enzyme in methionine biosynthesis - homoserine trans-succinylase (HTS) - is unstable and subject to energy-dependent proteolysis. The enzyme is stable in triple mutants defective in Lon-, HslVU- and ClpP-dependent proteases. The instability of the protein is determined by the amino-terminal part of the protein, and its removal or substitution by the N-terminal part of beta-galactosidase confers stability. The effect of the amino-terminal segment is not caused by the N-end rule, as substitution of the first amino acid does not affect the stability of the protein. HTS is the first biosynthetic E. coli enzyme shown to have a short half-life and may represent a group of biosynthetic enzymes whose expression is controlled by proteolysis. Alternatively, the proteolytic processing of HTS may be unique to this enzyme and could reflect its central role in regulating bacterial growth, especially at elevated temperatures.     

The Escherichia coli DjlA and CbpA proteins can substitute for DnaJ in DnaK-mediated protein disaggregation

The DnaJ (Hsp40) protein of Escherichia coli serves as a cochaperone of DnaK (Hsp70), whose activity is involved in protein folding, protein targeting for degradation, and rescue of proteins from aggregates. Two other E. coli proteins, CbpA and DjlA, which exhibit homology with DnaJ, are known to interact with DnaK and to stimulate its chaperone activity. Although it has been shown that in dnaJ mutants both CbpA and DjlA are essential for growth at temperatures above 37 degrees C, their in vivo role is poorly understood. Here we show that in a dnaJ mutant both CbpA and DjlA are required for efficient protein dissaggregation at 42 degrees C.     

The effect of amyloidogenic peptides on bacterial aging correlates with their intrinsic aggregation propensity

The formation of aggregates by misfolded proteins is thought to be inherently toxic, affecting cell fitness. This observation has led to the suggestion that selection against protein aggregation might be a major constraint on protein evolution. The precise fitness cost associated with protein aggregation has been traditionally difficult to evaluate. Moreover, it is not known if the detrimental effect of aggregates on cell physiology is generic or depends on the specific structural features of the protein deposit. In bacteria, the accumulation of intracellular protein aggregates reduces cell reproductive ability, promoting cellular aging. Here, we exploit the cell division defects promoted by the intracellular aggregation of Alzheimer's-disease-related amyloid β peptide in bacteria to demonstrate that the fitness cost associated with protein misfolding and aggregation is connected to the protein sequence, which controls both the in vivo aggregation rates and the conformational properties of the aggregates. We also show that the deleterious impact of protein aggregation on bacterial division can be buffered by molecular chaperones, likely broadening the sequential space on which natural selection can act. Overall, the results in the present work have potential implications for the evolution of proteins and provide a robust system to experimentally model and quantify the impact of protein aggregation on cell fitness.     

Protein aggregation in Escherichia coli: role of proteases

Protein aggregation is involved in several human diseases, and presumed to be an important process in protein quality control. In bacteria, aggregation of proteins occurs during stress conditions, such as heat shock. We studied the protein aggregates of Escherichia coli during heat shock. Our results demonstrate that the concentration and diversity of proteins in the aggregates depend on the availability of proteases. Aggregates obtained from mutants in the Lon (La) protease contain three times more protein than wild-type aggregates and show the broadest protein diversity. The results support the assumption that protein aggregates are formed from partially unfolded proteins that were not refolded by chaperones or degraded by proteases.     

Isomerase-independent chaperone function of cyclophilin ensures aggregation prevention of adenosine kinase both in vitro and under in vivo conditions

Using inactive aggregates of adenosine kinase (AdK) from Leishmania donovani as the model substrate, we recently demonstrated that a cyclophilin (LdCyP) from the same source in an isomerase-independent fashion reactivated the enzyme in vitro by disaggregating its inactive oligomers [Chakraborty et al. (2002) J. Biol. Chem. 277, 47451-47460]. Besides disrupting preformed aggregates, LdCyP also prevents reaggregation of the newly formed active protein that is generated after productive refolding from its urea-denatured state. To investigate possible physiological implications of such phenomena, a unique expression system that simultaneously induces both AdK and LdCyP in naturally AdK-deficient Escherichia coli, was developed. Both in vitro and in vivo experiments revealed that oligomerization is an inherent property of this particular enzyme. In vivo protein cross-linking studies, activity determination analysis and Ado phosphorylation experiments carried out in cells coexpressing both the proteins unequivocally demonstrated that, similar to the phenomena observed in vitro, aggregates of the enzyme formed in vivo are able to interact with both LdCyP and its N-terminal truncated form (N(22-88)DEL LdCyP) in a crowded intracellular environment, resulting in aggregation prevention and reactivation of the enzyme. Our results indicate that the isomerase-independent chaperone function of LdCyP, detected in vitro, participates in vivo as well to keep aggregation-prone proteins in a monomeric state. Furthermore, analogous to yeast/bacterial two-hybrid systems, development of this simple coexpression system may help in the confirmation of interaction of two proteins under simulated in vivo conditions.     

The chemical chaperone proline relieves the thermosensitivity of a dnaK deletion mutant at 42 degrees C

Since, like other osmolytes, proline can act as a protein stabilizer, we investigated the thermoprotectant properties of proline in vitro and in vivo. In vivo, elevated proline pools in Escherichia coli (obtained by altering the feedback inhibition by proline of gamma-glutamylkinase, the first enzyme of the proline biosynthesis pathway) restore the viability of a dnaK-deficient mutant at 42 degrees C, suggesting that proline can act as a thermoprotectant for E. coli cells. Furthermore, analysis of aggregated proteins in the dnaK-deficient strain at 42 degrees C by two-dimensional gel electrophoresis shows that high proline pools reduce the protein aggregation defect of the dnaK-deficient strain. In vitro, like other "chemical chaperones," and like the DnaK chaperone, proline protects citrate synthase against thermodenaturation and stimulates citrate synthase renaturation after urea denaturation. These results show that a protein aggregation defect can be compensated for by a single mutation in an amino acid biosynthetic pathway and that an ubiquitously producible chemical chaperone can compensate for a defect in one of the major chaperones involved in protein folding and aggregation.     

The enigmatic acyl carrier protein phosphodiesterase of Escherichia coli: genetic and enzymological characterization

The acyl carrier proteins (ACPs) of fatty acid synthesis are functional only when modified by attachment of the prosthetic group, 4'-phosphopantetheine (4'-PP), which is transferred from CoA to the hydroxyl group of a specific serine residue. Almost 40 years ago Vagelos and Larrabee reported an enzyme from Escherichia coli that removed the prosthetic group. We report that this enzyme, called ACP hydrolyase or ACP phosphodiesterase, is encoded by a gene (yajB) of previously unknown function that we have renamed acpH. A mutant E. coli strain having a total deletion of the acpH gene has been constructed that grows normally, showing that phosphodiesterase activity is not essential for growth, although it is required for turnover of the ACP prosthetic group in vivo. ACP phosphodiesterase (AcpH) has been purified to homogeneity for the first time and is a soluble protein that very readily aggregates upon overexpression in vivo or concentration in vitro. The purified enzyme has been shown to cleave acyl-ACP species with acyl chains of 6-16 carbon atoms and is active on some, but not all, non-native ACP species tested. Possible physiological roles for AcpH are discussed.     

Exploring New Biological Functions of Amyloids: Bacteria Cell Agglutination Mediated by Host Protein Aggregation

Antimicrobial proteins and peptides (AMPs) are important effectors of the innate immune system that play a vital role in the prevention of infections. Recent advances have highlighted the similarity between AMPs and amyloid proteins. Using the Eosinophil Cationic Protein as a model, we have rationalized the structure-activity relationships between amyloid aggregation and antimicrobial activity. Our results show how protein aggregation can induce bacteria agglutination and cell death. Using confocal and total internal reflection fluorescence microscopy we have tracked the formation in situ of protein amyloid-like aggregates at the bacteria surface and on membrane models. In both cases, fibrillar aggregates able to bind to amyloid diagnostic dyes were detected. Additionally, a single point mutation (Ile13 to Ala) can suppress the protein amyloid behavior, abolishing the agglutinating activity and impairing the antimicrobial action. The mutant is also defective in triggering both leakage and lipid vesicle aggregation. We conclude that ECP aggregation at the bacterial surface is essential for its cytotoxicity. Hence, we propose here a new prospective biological function for amyloid-like aggregates with potential biological relevance.     

Membrane docking of an aggregation-prone protein improves its solubilization

We used preS2-S'-beta-galactosidase, a three domain fusion protein that aggregates extensively at 43 degrees C in the cytoplasm of Escherichia coli to search for multicopy suppressors of protein aggregation and inclusion bodies formation, and took advantage of the known differential solubility of preS2-S'-beta-galactosidase at 37 and 43 degrees C to develop a selection procedure for the gene products that would prevent its aggregation in vivo at 43 degrees C. First, we demonstrate that the differential solubility of preS2-S'-beta-galactosidase results in a lactose-positive phenotype at 37 degrees C as opposed to a lactose-negative phenotype at 43 degrees C. We searched for multicopy suppressors of preS2-S'-beta-galactosidase aggregation at 43 degrees C by selecting pink lactose-positive colonies on a background of white lactose-negative colonies after transformation of bacteria with an E. coli gene bank. We found only two multicopy suppressors of preS2-S'-beta-galactosidase aggregation at 43 degrees C, protein isoaspartate methyltransferase (PIMT) and the membrane components ChbBC of the N,N'-diacetylchitobiose phosphotransferase transporter. We have previously shown that PIMT overexpression reduces the level of isoaspartate in preS2-S'-beta-galactosidase, increases its thermal stability and consequently helps in its solubilization at 43 degrees C (Kern et al., J. Bacteriol. 187, 1377-1383). In the present work, we show that ChbBC overexpression targets a fraction of preS2-S'-beta-galactosidase to the membrane, and decreases its amount in inclusion bodies, which results in its decreased thermodenaturation and in a lactose-positive phenotype at 43 degrees C. Cross-linking experiments show that the inner membrane protein ChbC interacts with preS2-S'-beta-galactosidase. Our results suggest that membrane docking of aggregation-prone proteins might be a useful method for their solubilization.     

Tools for the study of protein quality control systems: use of truncated homoserine trans-succinylase as a model substrate for ATP-dependent proteolysis in Escherichia coli

Protein quality control, mediated by chaperones and ATP-dependent proteases, is essential for maintaining balanced growth and for regulating critical processes. To study these systems it is necessary to have model substrate proteins. However, most cellular proteins are stable and the few unstable proteins are usually regulatory and present in low concentrations, making them unsuitable for studies, especially in vivo. We present HTS(Delta1-6), a truncated homoserine trans-succinylase (HTS) which is unstable, can be expressed at high levels and has an enzymatic, measurable, activity. This protein can serve as a good model substrate for Escherichia coli ATP-dependent proteolysis.     

Protein isoaspartate methyltransferase is a multicopy suppressor of protein aggregation in Escherichia coli

We used preS2-S'-beta-galactosidase, a three-domain fusion protein that aggregates extensively at 43 degrees C in the cytoplasm of Escherichia coli, to search for multicopy suppressors of protein aggregation and inclusion body formation and took advantage of the known differential solubility of preS2-S'-beta-galactosidase at 37 and 43 degrees C to develop a selection procedure for the gene products that would prevent its aggregation in vivo at 43 degrees C. First, we demonstrate that the differential solubility of preS2-S'-beta-galactosidase results in a lactose-positive phenotype at 37 degrees C as opposed to a lactose-negative phenotype at 43 degrees C. We searched for multicopy suppressors of preS2-S'-beta-galactosidase aggregation by selecting pink lactose-positive colonies on a background of white lactose-negative colonies at 43 degrees C after transformation of bacteria with an E. coli gene bank. We discovered that protein isoaspartate methyltransferase (PIMT) is a multicopy suppressor of preS2-S'-beta-galactosidase aggregation at 43 degrees C. Overexpression of PIMT reduces the amount of preS2-S'-beta-galactosidase found in inclusion bodies at 43 degrees C and increases its amount in soluble fractions. It reduces the level of isoaspartate formation in preS2-S'-beta-galactosidase and increases its thermal stability in E. coli crude extracts without increasing the thermostability of a control protein, citrate synthase, in the same extracts. We could not detect any induction of the heat shock response resulting from PIMT overexpression, as judged from amounts of DnaK and GroEL, which were similar in the PIMT-overproducing and control strains. These results suggest that PIMT might be overburdened in some physiological conditions and that its overproduction may be beneficial in conditions in which protein aggregation occurs, for example, during biotechnological protein overproduction or in protein aggregation diseases.     

Chaperone action of a versatile small heat shock protein from Methanococcoides burtonii, a cold adapted archaeon

The Methanococcoides burtonii small heat shock protein (Mb-sHsp) is an alphaB-crystallin homolog that delivers protein stabilizing and protective functions to model enzymes, presumably reflecting its role as a molecular chaperone in vivo. Although the gene encoding Mb-shsp was cloned from a cold-adapted microorganism, the Mb-sHsp is an efficient protein chaperone at temperatures far above the optimum growth temperature of M. burtonii. We show that Mb-sHsp can prevent aggregation in E. coli cell free extracts at 60 degrees C for 4 h and can stabilize bovine liver glutamate dehydrogenase for 3 h at 50 degrees C. Surface plasmon resonance was used to determine the binding affinity of Mb-sHsp for denatured proteins. Mb-sHsp bound tightly to denatured lysozyme but not to the native form. When Mb-Cpn and Mg(2+)-ATP were added to the reaction, bound lysozyme was released from Mb-sHsp establishing that Mb-Cpn is able to off-load folding intermediates from Mb-sHsp. In addition, Mb-sHsp and Mb-Cpn also function cooperatively to protect an enzyme substrate. Through characterization of these M. burtonii chaperones, we were able to reconstitute a key heat shock regulated protein folding function of this cold adapted organism in vitro.     

Investigating the effects of mutations on protein aggregation in the cell

The conversion of peptides and proteins into highly ordered and intractable aggregates is associated with a range of debilitating human diseases and represents a widespread problem in biotechnology. Protein engineering studies carried out in vitro have shown that mutations promote aggregation when they either destabilize the native state of a globular protein or accelerate the conversion of unfolded or partially folded conformations into oligomeric structures. We have extended such studies to investigate protein aggregation in vivo where a number of additional factors able to modify dramatically the aggregation behavior of proteins are present. We have expressed, in Escherichia coli cells, an E. coli protein domain, HypF-N. The results for a range of mutational variants indicate that although mutants with a conformational stability similar to that of the wild-type protein are soluble in the E. coli cytosol, variants with single point mutations predicted to destabilize the protein invariably aggregate after expression. We show, however, that aggregation of destabilized variants can be prevented by incorporating multiple mutations designed to reduce the intrinsic propensity of the polypeptide chain to aggregate; in the cases discussed here, this is achieved by an increase in the net charge of the protein. These results suggest that the principles being established to rationalize aggregation behavior in vitro have general validity for situations in vivo where aggregation has both biotechnological and medical relevance.     

Effect of temperature on stability and activity of elongation factor 2 proteins from Antarctic and thermophilic methanogens

Despite the presence and abundance of archaea in low-temperature environments, little information is available regarding their physiological and biochemical properties. In order to investigate the adaptation of archaeal proteins to low temperatures, we purified and characterized the elongation factor 2 (EF-2) protein from the Antarctic methanogen Methanococcoides burtonii, which was expressed in Escherichia coli, and compared it to the recombinant EF-2 protein from a phylogenetically related thermophile, Methanosarcina thermophila. Using differential scanning calorimetry to assess protein stability and enzyme assays for the intrinsic GTPase activity, we identified biochemical and biophysical properties that are characteristic of the cold-adapted protein. This includes a higher activity at low temperatures caused by a decrease of the activation energy necessary for GTP hydrolysis and a decreased activation energy for the irreversible denaturation of the protein, which indicates a less thermostable structure. Comparison of the in vitro properties of the proteins with the temperature-dependent characteristics of growth of the organisms indicates that additional cytoplasmic factors are likely to be important for the complete thermal adaptation of the proteins in vivo. This is the first study to address thermal adaptation of proteins from a free-living, cold-adapted archaeon, and our results indicate that the ability of the Antarctic methanogen to adapt to the cold is likely to involve protein structural changes.     

Solubilization of protein aggregates by the acid stress chaperones HdeA and HdeB

The acid stress chaperones HdeA and HdeB of Escherichia coli prevent the aggregation of periplasmic proteins at acidic pH. We show in this report that they also form mixed aggregates with proteins that have failed to be solubilized at acidic pH and allow their subsequent solubilization at neutral pH. HdeA, HdeB, and HdeA and HdeB together display an increasing efficiency for the solubilization of protein aggregates at pH 3. They are less efficient for the solubilization of aggregates at pH 2, whereas HdeB is the most efficient. Increasing amounts of periplasmic proteins draw increasing amounts of chaperone into pellets, suggesting that chaperones co-aggregate with their substrate proteins. We observed a decrease in the size of protein aggregates in the presence of HdeA and HdeB, from very high molecular mass aggregates to 100-5000-kDa species. Moreover, a marked decrease in the exposed hydrophobicity of aggregated proteins in the presence of HdeA and HdeB was revealed by 1,1'-bis(4-anilino)naphtalene-5,5'-disulfonic acid binding experiments. In vivo, during the recovery at neutral pH of acid stressed bacterial cells, HdeA and HdeB allow the solubilization and renaturation of protein aggregates, including those formed by the maltose receptor MalE, the oligopeptide receptor OppA, and the histidine receptor HisJ. Thus, HdeA and HdeB not only help to maintain proteins in a soluble state during acid treatment, as previously reported, but also assist, both in vitro and in vivo, in the solubilization at neutral pH of mixed protein-chaperone aggregates formed at acidic pH, by decreasing the size of protein aggregates and the exposed hydrophobicity of aggregated proteins.     

Amyloid formation modulates the biological activity of a bacterial protein

The aggregation of proteins into amyloid fibrils is the hallmark feature of a group of late-onset degenerative diseases including Alzheimer, Parkinson, and prion diseases. We report here that microcin E492, a peptide naturally produced by Klebsiella pneumoniae that kills bacteria by forming pores in the cytoplasmic membrane, assembles in vitro into amyloid-like fibrils. The fibrils have the same structural, morphological, tinctorial, and biochemical properties as the aggregates observed in the disease conditions. In addition, we found that amyloid formation also occurs in vivo where it is associated with a loss of toxicity of the protein. The finding that microcin E492 naturally exists both as functional toxic pores and as harmless fibrils suggests that protein aggregation into amyloid fibrils is an evolutionarily conserved property of proteins that can be successfully employed by bacteria to fulfill specific physiological needs.     

Identification of thermolabile Escherichia coli proteins: prevention and reversion of aggregation by DnaK and ClpB

We systematically analyzed the capability of the major cytosolic chaperones of Escherichia coli to cope with protein misfolding and aggregation during heat stress in vivo and in cell extracts. Under physiological heat stress conditions, only the DnaK system efficiently prevented the aggregation of thermolabile proteins, a surprisingly high number of 150-200 species, corresponding to 15-25% of detected proteins. Identification of thermolabile DnaK substrates by mass spectrometry revealed that they comprise 80% of the large (>/=90 kDa) but only 18% of the small (相似文献   

Effect of temperature on the expression of wild-type and thermostable mutants of kanamycin nucleotidyltransferase in Escherichia coli.

The expression of kanamycin nucleotidyltransferase (KNTase) in Escherichia coli results in different forms of the protein, depending on the temperature; soluble active enzyme is synthesized at 23 degrees C but the protein is mostly aggregated and inactive in inclusion bodies when made at 37 degrees C. However, active enzyme can be recovered by solubilization of the inclusion bodies with 8 M urea followed by dilution of the denaturant, indicating that the polypeptide is not damaged covalently but is present in a misfolded state. The availability of thermostable mutants of KNTase allows a test of the hypothesis that formation of inclusion bodies when proteins are highly expressed in E. coli is due to the accumulation of a folding intermediate that is prone to temperature-dependent aggregation. Because these mutants were isolated by cloning the KNTase gene into the thermophile Bacillus stearothermophilus and selecting for kanamycin resistance at high growth temperatures, they must be thermostable for both synthesis and activity and must have folding intermediates that are less susceptible to the formation of aggregates. Indeed, whereas decreasing the temperature from 37 to 23 degrees C increased the KNTase specific activity 10-fold in cells expressing the wild-type enzyme, this change resulted in only a 2.1-fold increase for the TK1 (Asp80----Tyr) mutant and a 1.7-fold increase for the TK101 (Asp80----Tyr and Thr130----Lys) double mutant. The strategy of cloning in thermophiles and selecting or screening for mutants that fold correctly to yield biological activity at high growth temperatures may be useful in overcoming the problem of the insolubility of some proteins when expressed in heterologous hosts.     

Genetic dissection of specificity determinants in the interaction of HPr with enzymes II of the bacterial phosphoenolpyruvate:sugar phosphotransferase system in Escherichia coli

The histidine protein (HPr) is the energy-coupling protein of the phosphoenolpyruvate (PEP)-dependent carbohydrate:phosphotransferase system (PTS), which catalyzes sugar transport in many bacteria. In its functions, HPr interacts with a number of evolutionarily unrelated proteins. Mainly, it delivers phosphoryl groups from enzyme I (EI) to the sugar-specific transporters (EIIs). HPr proteins of different bacteria exhibit almost identical structures, and, where known, they use similar surfaces to interact with their target proteins. Here we studied the in vivo effects of the replacement of HPr and EI of Escherichia coli with the homologous proteins from Bacillus subtilis, a gram-positive bacterium. This replacement resulted in severe growth defects on PTS sugars, suggesting that HPr of B. subtilis cannot efficiently phosphorylate the EIIs of E. coli. In contrast, activation of the E. coli BglG regulatory protein by HPr-catalyzed phosphorylation works well with the B. subtilis HPr protein. Random mutations were introduced into B. subtilis HPr, and a screen for improved growth on PTS sugars yielded amino acid changes in positions 12, 16, 17, 20, 24, 27, 47, and 51, located in the interaction surface of HPr. Most of the changes restore intermolecular hydrophobic interactions and salt bridges normally formed by the corresponding residues in E. coli HPr. The residues present at the targeted positions differ between HPrs of gram-positive and -negative bacteria, but within each group they are highly conserved. Therefore, they may constitute a signature motif that determines the specificity of HPr for either gram-negative or -positive EIIs.     

Escherichia coli DnaK and GrpE heat shock proteins interact both in vivo and in vitro.

Previous studies have demonstrated that the Escherichia coli dnaK and grpE genes code for heat shock proteins. Both the Dnak and GrpE proteins are necessary for bacteriophage lambda DNA replication and for E. coli growth at all temperatures. Through a series of genetic and biochemical experiments, we have shown that these heat shock proteins functionally interact both in vivo and in vitro. The genetic evidence is based on the isolation of mutations in the dnaK gene, such as dnaK9 and dnaK90, which suppress the Tr- phenotype of bacteria carrying the grpE280 mutation. Coimmunoprecipitation of DnaK+ and GrpE+ proteins from cell lysates with anti-DnaK antibodies demonstrated their interaction in vitro. In addition, the DnaK756 and GrpE280 mutant proteins did not coimmunoprecipitate efficiently with the GrpE+ and DnaK+ proteins, respectively, suggesting that interaction between the DnaK and GrpE proteins is necessary for E. coli growth, at least at temperatures above 43 degrees C. Using this assay, we found that one of the dnaK suppressor mutations, dnaK9, reinstated a protein-protein interaction between the suppressor DnaK9 and GrpE280 proteins.