Hsp33 Controls Elongation Factor-Tu Stability and Allows Escherichia coli Growth in the Absence of the Major DnaK and Trigger Factor Chaperones

Intracellular de novo protein folding is assisted by cellular networks of molecular chaperones. In Escherichia coli, cooperation between the chaperones trigger factor (TF) and DnaK is central to this process. Accordingly, the simultaneous deletion of both chaperone-encoding genes leads to severe growth and protein folding defects. Herein, we took advantage of such defective phenotypes to further elucidate the interactions of chaperone networks in vivo. We show that disruption of the TF/DnaK chaperone pathway is efficiently rescued by overexpression of the redox-regulated chaperone Hsp33. Consistent with this observation, the deletion of hslO, the Hsp33 structural gene, is no longer tolerated in the absence of the TF/DnaK pathway. However, in contrast with other chaperones like GroEL or SecB, suppression by Hsp33 was not attributed to its potential overlapping general chaperone function(s). Instead, we show that overexpressed Hsp33 specifically binds to elongation factor-Tu (EF-Tu) and targets it for degradation by the protease Lon. This synergistic action of Hsp33 and Lon was responsible for the rescue of bacterial growth in the absence of TF and DnaK, by presumably restoring the coupling between translation and the downstream folding capacity of the cell. In support of this hypothesis, we show that overexpression of the stress-responsive toxin HipA, which inhibits EF-Tu, also rescues bacterial growth and protein folding in the absence of TF and DnaK. The relevance for such a convergence of networks of chaperones and proteases acting directly on EF-Tu to modulate the intracellular rate of protein synthesis in response to protein aggregation is discussed.     

Defining the role of the Escherichia coli chaperone SecB using comparative proteomics

To improve understanding and identify novel substrates of the cytoplasmic chaperone SecB in Escherichia coli, we analyzed a secB null mutant using comparative proteomics. The secB null mutation did not affect cell growth but caused significant differences at the proteome level. In the absence of SecB, dynamic protein aggregates containing predominantly secretory proteins accumulated in the cytoplasm. Unprocessed secretory proteins were detected in radiolabeled whole cell lysates. Furthermore, the assembly of a large fraction of the outer membrane proteome was slowed down, whereas its steady state composition was hardly affected. In response to aggregation and delayed sorting of secretory proteins, cytoplasmic chaperones DnaK, GroEL/ES, ClpB, IbpA/B, and HslU were up-regulated severalfold, most likely to stabilize secretory proteins during their delayed translocation and/or rescue aggregated secretory proteins. The SecB/A dependence of 12 secretory proteins affected by the secB null mutation (DegP, FhuA, FkpA, OmpT, OmpX, OppA, TolB, TolC, YbgF, YcgK, YgiW, and YncE) was confirmed by "classical" pulse-labeling experiments. Our study more than triples the number of known SecB-dependent secretory proteins and shows that the primary role of SecB is to facilitate the targeting of secretory proteins to the Sec-translocase.     

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.     

Physical Interaction between Bacterial Heat Shock Protein (Hsp) 90 and Hsp70 Chaperones Mediates Their Cooperative Action to Refold Denatured Proteins

In eukaryotes, heat shock protein 90 (Hsp90) is an essential ATP-dependent molecular chaperone that associates with numerous client proteins. HtpG, a prokaryotic homolog of Hsp90, is essential for thermotolerance in cyanobacteria, and in vitro it suppresses the aggregation of denatured proteins efficiently. Understanding how the non-native client proteins bound to HtpG refold is of central importance to comprehend the essential role of HtpG under stress. Here, we demonstrate by yeast two-hybrid method, immunoprecipitation assays, and surface plasmon resonance techniques that HtpG physically interacts with DnaJ2 and DnaK2. DnaJ2, which belongs to the type II J-protein family, bound DnaK2 or HtpG with submicromolar affinity, and HtpG bound DnaK2 with micromolar affinity. Not only DnaJ2 but also HtpG enhanced the ATP hydrolysis by DnaK2. Although assisted by the DnaK2 chaperone system, HtpG enhanced native refolding of urea-denatured lactate dehydrogenase and heat-denatured glucose-6-phosphate dehydrogenase. HtpG did not substitute for DnaJ2 or GrpE in the DnaK2-assisted refolding of the denatured substrates. The heat-denatured malate dehydrogenase that did not refold by the assistance of the DnaK2 chaperone system alone was trapped by HtpG first and then transferred to DnaK2 where it refolded. Dissociation of substrates from HtpG was either ATP-dependent or -independent depending on the substrate, indicating the presence of two mechanisms of cooperative action between the HtpG and the DnaK2 chaperone system.     

Investigation of the interaction between DnaK and DnaJ by surface plasmon resonance spectroscopy.

Hsp70 chaperones assist protein folding through ATP-regulated transient association with substrates. Substrate binding by Hsp70 is controlled by DnaJ co-chaperones which stimulate Hsp70 to hydrolyze ATP and, consequently, to close its substrate binding cavity allowing trapping of substrates. We analyzed the interaction of the Escherichia coli Hsp70 homologue, DnaK, with DnaJ using surface plasmon resonance (SPR) spectroscopy. Resonance signals of complex kinetic characteristics were detected when DnaK was passed over a sensor chip with coupled DnaJ. This interaction was specific as it was not detected with a functionally defective DnaJ mutant protein, DnaJ259, that carries a mutation in the HPD signature motif of the conserved J-domain. Detectable DnaK-DnaJ interaction required ATP hydrolysis by DnaK and was competitively inhibited by chaperone substrates of DnaK. For DnaK mutant proteins with amino acid substitutions in the substrate binding cavity that affect substrate binding, the strength of detected interaction with DnaJ decreased proportionally with increased strength of the substrate binding defects. These findings indicate that the detected response signals resulted from DnaJ and ATP hydrolysis-dependent association of DnaJ as substrate for DnaK. Although not considered as physiologically relevant, this association allowed us to experimentally unravel the mechanism of DnaJ action. Accordingly, DnaJ stimulates ATP hydrolysis only after association of a substrate with the substrate binding cavity of DnaK. Further analysis revealed that this coupling mechanism required the J-domain of DnaJ and was also functional for natural DnaK substrates, and thus is central to the mechanism of action of the DnaK chaperone system.     

DnaJ recruits DnaK to protein aggregates

Thermal stress might lead to protein aggregation in the cell. Reactivation of protein aggregates depends on Hsp100 and Hsp70 chaperones. We focus in this study on the ability of DnaK, the bacterial representative of the Hsp70 family, to interact with different aggregated model substrates. Our data indicate that DnaK binding to large protein aggregates is mediated by DnaJ, and therefore it depends on its affinity for the cochaperone. Mutations in the structural region of DnaK known as the "latch" decrease the affinity of the chaperone for DnaJ, resulting in a defective activity as protein aggregate-removing agent. As expected, the chaperone activity is recovered when DnaJ concentration is raised to overcome the lower affinity of the mutant for the cochaperone, suggesting that a minimum number of aggregate-bound DnaK molecules is necessary for its efficient reactivation. Our results provide the first experimental evidence of DnaJ-mediated recruiting of ATP-DnaK molecules to the aggregate surface.     

Crystal structure of DnaK protein complexed with nucleotide exchange factor GrpE in DnaK chaperone system: insight into intermolecular communication

The conserved, ATP-dependent bacterial DnaK chaperones process client substrates with the aid of the co-chaperones DnaJ and GrpE. However, in the absence of structural information, how these proteins communicate with each other cannot be fully delineated. For the study reported here, we solved the crystal structure of a full-length Geobacillus kaustophilus HTA426 GrpE homodimer in complex with a nearly full-length G. kaustophilus HTA426 DnaK that contains the interdomain linker (acting as a pseudo-substrate), and the N-terminal nucleotide-binding and C-terminal substrate-binding domains at 4.1-Å resolution. Each complex contains two DnaKs and two GrpEs, which is a stoichiometry that has not been found before. The long N-terminal GrpE α-helices stabilize the linker of DnaK in the complex. Furthermore, interactions between the DnaK substrate-binding domain and the N-terminal disordered region of GrpE may accelerate substrate release from DnaK. These findings provide molecular mechanisms for substrate binding, processing, and release during the Hsp70 chaperone cycle.     

Influence of impaired chaperone or secretion function on SecB production in Escherichia coli.

The efficient export of proteins through the cytoplasmic membrane of Escherichia coli requires chaperones to maintain protein precursors in a translocation-competent conformation. In addition to SecB, the major chaperone facilitating export of particular precursors, heat shock-induced chaperones DnaK-DnaJ and GroEL-GroES are also involved in this process. By use of secB'-lacZ gene fusions and immunoprecipitation experiments, SecB production was studied in E. coli strains containing conditional lethal mutations in chaperone or sec genes. While the loss of heat shock chaperones resulted in an increased production of SecB, mutations in sec genes showed only minor effects on SecB synthesis. Neither the plasmid-mediated overexpression of precursors of exoproteins nor the overexpression of secB altered the synthesis of SecB. These results suggest that under conditions where chaperones become depleted, E. coli responds by raising the expression of secB. These data confirm the supposed synergy of different chaperones involved in protein export.     

Existence of abnormal protein aggregates in healthy Escherichia coli cells

Protein aggregation is a phenomenon observed in all organisms and has often been linked with cell disorders. In addition, several groups have reported a virtual absence of protein aggregates in healthy cells. In contrast to previous studies and the expected outcome, we observed aggregated proteins in aerobic exponentially growing and “healthy” Escherichia coli cells. We observed overrepresentation of “aberrant proteins,” as well as substrates of the major conserved chaperone DnaK (Hsp70) and the protease ClpXP (a serine protease), in the aggregates. In addition, the protein aggregates appeared to interact with chaperones known to be involved in the aggregate repair pathway, including ClpB, GroEL, GroES, and DnaK. Finally, we showed that the levels of reactive oxygen species and unfolded or misfolded proteins determine the levels of protein aggregates. Our results led us to speculate that protein aggregates may function as a temporary “trash organelle” for cellular detoxification.     

Effects of pre-protein overexpression on SecB synthesis in Escherichia coli

Protein translocation through the cytoplasmic membrane of Escherichia coli involves cytosolic chaperones. The export-dedicated chaperone SecB mediates targeting of a subset of pre-proteins. In this report, synthesis of SecB in response to plasmid-mediated overexpression of pre-proteins was studied. Overexpression of SecB-dependent pre-proteins stimulated synthesis of SecB under conditions where the cellular export capacity was saturated or uncomplexed SecB was trapped. On the contrary, overexpression of SecB-independent pre-beta-lactamase reduced the promoter activity of secB. The results suggest that uncomplexed SecB can be sequestered by synthesis of SecB-dependent pre-proteins. Furthermore, these data demonstrate the distinct action of the SecB- and signal recognition particle-dependent protein targeting pathways.     

Structural Insights into the Chaperone Activity of the 40-kDa Heat Shock Protein DnaJ: BINDING AND REMODELING OF A NATIVE SUBSTRATE*

Hsp40 chaperones bind and transfer substrate proteins to Hsp70s and regulate their ATPase activity. The interaction of Hsp40s with native proteins modifies their structure and function. A good model for this function is DnaJ, the bacterial Hsp40 that interacts with RepE, the repressor/activator of plasmid F replication, and together with DnaK regulates its function. We characterize here the structure of the DnaJ-RepE complex by electron microscopy, the first described structure of a complex between an Hsp40 and a client protein. The comparison of the complexes of DnaJ with two RepE mutants reveals an intrinsic plasticity of the DnaJ dimer that allows the chaperone to adapt to different substrates. We also show that DnaJ induces conformational changes in dimeric RepE, which increase the intermonomeric distance and remodel both RepE domains enhancing its affinity for DNA.     

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.     

Chaperone over-expression in Escherichia coli: Apparent increased yields of soluble recombinant protein kinases are due mainly to soluble aggregates

The recombinant expression of eukaryotic proteins in Escherichia coli often results in protein aggregation. Several articles report on improved solubility and increased purification yields of individual proteins upon over-expression of E. coli chaperones but this effect might potentially be protein-specific. To find out whether chaperone over-expression is a generally applicable strategy for the production of human protein kinases in E. coli, we analyzed 10 kinases, mainly as catalytic domain constructs. The kinases studied, namely c-Src, c-Abl, Hck, Lck, Igf1R, InsR, KDR, c-Met, b-Raf and Irak4, belong to the tyrosine and tyrosine kinase-like groups of kinases. Upon over-expression of the E. coli chaperones DnaK/DnaJ/GrpE and GroEL/GroES, the yields of 7 from 10 polyhistidine-tagged kinases were increased up to 5-fold after nickel-affinity purification (IMAC). Additive over-expression of the chaperones ClpB and/or trigger factor showed no further improvement. Co-purification of DnaJ and GroEL indicated incomplete kinase folding, therefore, the oligomerization state of the kinases was determined by size-exclusion chromatography. In our study, kinases behave in three different ways. Kinases where yields are not affected by E. coli chaperone over-expression e.g. c-Src elute in the monomeric fraction (category I). Although IMAC yields increase upon chaperone over-expression, InsR and b-Raf kinase are present as soluble aggregates (category II). Igf1R and c-Met kinase catalytic domains are partially complexed with E. coli chaperones upon over-expression; however, they show 2-fold increased yields of monomer (category III). Together, our results suggest that the benefits of chaperone over-expression on the production of protein kinases in E. coli are indeed case-specific.     

Quality control of a molybdoenzyme by the Lon protease

Molybdoenzymes contain a molybdenum cofactor in their active site to catalyze various redox reactions in all domains of life. To decipher crucial steps during their biogenesis, the TorA molybdoenzyme of Escherichia coli had played a major role to understand molybdoenzyme maturation process driven by specific chaperones. TorD, the specific chaperone of TorA, is also involved in TorA protection. Here, we show that immature TorA (apoTorA) is degraded in vivo and in vitro by the Lon protease. Lon interacts with apoTorA but not with holoTorA. Lon and TorD compete for apoTorA binding but TorD binding protects apoTorA against degradation. Lon is the first protease shown to eliminate an immature or misfolded molybdoenzyme probably by targeting its inactive catalytic site.     

Chaperone networking facilitates protein targeting to the bacterial cytoplasmic membrane

Nascent polypeptides emerging from the ribosome are assisted by a pool of molecular chaperones and targeting factors, which enable them to efficiently partition as cytosolic, integral membrane or exported proteins. Extensive genetic and biochemical analyses have significantly expanded our knowledge of chaperone tasking throughout this process. In bacteria, it is known that the folding of newly-synthesized cytosolic proteins is mainly orchestrated by three highly conserved molecular chaperones, namely Trigger Factor (TF), DnaK (HSP70) and GroEL (HSP60). Yet, it has been reported that these major chaperones are strongly involved in protein translocation pathways as well. This review describes such essential molecular chaperone functions, with emphasis on both the biogenesis of inner membrane proteins and the post-translational targeting of presecretory proteins to the Sec and the twin-arginine translocation (Tat) pathways. Critical interplay between TF, DnaK, GroEL and other molecular chaperones and targeting factors, including SecB, SecA, the signal recognition particle (SRP) and the redox enzyme maturation proteins (REMPs) is also discussed. This article is part of a Special Issue entitled: Protein trafficking and secretion in bacteria. Guest Editors: Anastassios Economou and Ross Dalbey.     

The Hsc66-Hsc20 Chaperone System in Escherichia coli: Chaperone Activity and Interactions with the DnaK-DnaJ-GrpE System

Hsc66, a stress-70 protein, and Hsc20, a J-type accessory protein, comprise a newly described Hsp70-type chaperone system in addition to DnaK-DnaJ-GrpE in Escherichia coli. Because endogenous substrates for the Hsc66-Hsc20 system have not yet been identified, we investigated chaperone-like activities of Hsc66 and Hsc20 by their ability to suppress aggregation of denatured model substrate proteins, such as rhodanese, citrate synthase, and luciferase. Hsc66 suppressed aggregation of rhodanese and citrate synthase, and ATP caused effects consistent with complex destabilization typical of other Hsp70-type chaperones. Differences in the activities of Hsc66 and DnaK, however, suggest that these chaperones have dissimilar substrate specificity profiles. Hsc20, unlike DnaJ, did not exhibit intrinsic chaperone activity and appears to function solely as a regulatory cochaperone protein for Hsc66. Possible interactions between the Hsc66-Hsc20 and DnaK-DnaJ-GrpE chaperone systems were also investigated by measuring the effects of cochaperone proteins on Hsp70 ATPase activities. The nucleotide exchange factor GrpE did not stimulate the ATPase activity of Hsc66 and thus appears to function specifically with DnaK. Cross-stimulation by the cochaperones Hsc20 and DnaJ was observed, but the requirement for supraphysiological concentrations makes it unlikely that these interactions occur significantly in vivo. Together these results suggest that Hsc66-Hsc20 and DnaK-DnaJ-GrpE comprise separate molecular chaperone systems with distinct, nonoverlapping cellular functions.     

An Integrated Proteomic Approach Uncovers Novel Substrates and Functions of the Lon Protease in Escherichia coli

Controlling the cellular abundance and proper function of proteins by proteolysis is a universal process in all living organisms. In Escherichia coli, the ATP‐dependent Lon protease is crucial for protein quality control and regulatory processes. To understand how diverse substrates are selected and degraded, unbiased global approaches are needed. We employed a quantitative Super‐SILAC (stable isotope labeling with amino acids in cell culture) mass spectrometry approach and compared the proteomes of a lon mutant and a strain producing the protease to discover Lon‐dependent physiological functions. To identify Lon substrates, we took advantage of a Lon trapping variant, which is able to translocate substrates but unable to degrade them. Lon‐associated proteins were identified by label‐free LC‐MS/MS. The combination of both approaches revealed a total of 14 novel Lon substrates. Besides the identification of known pathways affected by Lon, for example, the superoxide stress response, our cumulative data suggests previously unrecognized fundamental functions of Lon in sulfur assimilation, nucleotide biosynthesis, amino acid and central energy metabolism.     

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.