Heat-shock proteins can substitute for SecB function during protein export in Escherichia coli

How Quality Control Systems AID Sec-Dependent Protein Translocation

The evolutionarily conserved Sec machinery is responsible for transporting proteins across the cytoplasmic membrane. Protein substrates of the Sec machinery must be in an unfolded conformation in order to be translocated across (or inserted into) the cytoplasmic membrane. In bacteria, the requirement for unfolded proteins is strict: substrate proteins that fold (or misfold) prematurely in the cytoplasm prior to translocation become irreversibly trapped in the cytoplasm. Partially folded Sec substrate proteins and stalled ribosomes containing nascent Sec substrates can also inhibit translocation by blocking (i.e., “jamming”) the membrane-embedded Sec machinery. To avoid these issues, bacteria have evolved a complex network of quality control systems to ensure that Sec substrate proteins do not fold in the cytoplasm. This quality control network can be broken into three branches, for which we have defined the acronym “AID”: (i) avoidance of cytoplasmic intermediates through cotranslationally channeling newly synthesized Sec substrates to the Sec machinery; (ii) inhibition of folding Sec substrate proteins that transiently reside in the cytoplasm by molecular chaperones and the requirement for posttranslational modifications; (iii) destruction of products that could potentially inhibit translocation. In addition, several stress response pathways help to restore protein-folding homeostasis when environmental conditions that inhibit translocation overcome the AID quality control systems.

The Sec System: Protein Export in Escherichia coli

In Escherichia coli, proteins found in the periplasm or the outer membrane are exported from the cytoplasm by the general secretory, Sec, system before they acquire stably folded structure. This dynamic process involves intricate interactions among cytoplasmic and membrane proteins, both peripheral and integral, as well as lipids. In vivo, both ATP hydrolysis and proton motive force are required. Here, we review the Sec system from the inception of the field through early 2016, including biochemical, genetic, and structural data.

Multitasking SecB chaperones in bacteria

Protein export in bacteria is facilitated by the canonical SecB chaperone, which binds to unfolded precursor proteins, maintains them in a translocation competent state and specifically cooperates with the translocase motor SecA to ensure their proper targeting to the Sec translocon at the cytoplasmic membrane. Besides its key contribution to the Sec pathway, SecB chaperone tasking is critical for the secretion of the Sec-independent heme-binding protein HasA and actively contributes to the cellular network of chaperones that control general proteostasis in Escherichia coli, as judged by the significant interplay found between SecB and the trigger factor, DnaK and GroEL chaperones. Although SecB is mainly a proteobacterial chaperone associated with the presence of an outer membrane and outer membrane proteins, secB-like genes are also found in Gram-positive bacteria as well as in certain phages and plasmids, thus suggesting alternative functions. In addition, a SecB-like protein is also present in the major human pathogen Mycobacterium tuberculosis where it specifically controls a stress-responsive toxin–antitoxin system. This review focuses on such very diverse chaperone functions of SecB, both in E. coli and in other unrelated bacteria.

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.

Lon protease quality control of presecretory proteins in Escherichia coli and its dependence on the SecB and DnaJ (Hsp40) chaperones

Various environmental insults result in irreversible damage to proteins and protein complexes. To cope, cells have evolved dedicated protein quality control mechanisms involving molecular chaperones and proteases. Here, we provide both genetic and biochemical evidence that the Lon protease and the SecB and DnaJ/Hsp40 chaperones are involved in the quality control of presecretory proteins in Escherichia coli. We showed that mutations in the lon gene alleviate the cold-sensitive phenotype of a secB mutant. Such suppression was not observed with either clpP or clpQ protease mutants. In comparison to the respective single mutants, the double secB lon mutant strongly accumulates aggregates of SecB substrates at physiological temperatures, suggesting that the chaperone and the protease share substrates. These observations were extended in vitro by showing that the main substrates identified in secB lon aggregates, namely proOmpF and proOmpC, are highly sensitive to specific degradation by Lon. In contrast, both substrates are significantly protected from Lon degradation by SecB. Interestingly, the chaperone DnaJ by itself protects substrates better from Lon degradation than SecB or the complete DnaK/DnaJ/GrpE chaperone machinery. In agreement with this finding, a DnaJ mutant protein that does not functionally interact in vivo with DnaK efficiently suppresses the SecB cold-sensitive phenotype, highlighting the role of DnaJ in assisting presecretory proteins. Taken together, our data suggest that when the Sec secretion pathway is compromised, a pool of presecretory proteins is transiently maintained in a translocation-competent state and, thus, protected from Lon degradation by either the SecB or DnaJ chaperones.

Secretion of GOB metallo-beta-lactamase in Escherichia coli depends strictly on the cooperation between the cytoplasmic DnaK chaperone system and the Sec machinery: completion of folding and Zn(II) ion acquisition occur in the bacterial periplasm

Metallo-beta-lactamases (MbetaLs) are zinc-dependent enzymes produced by many clinically relevant gram-negative pathogens that can hydrolyze most beta-lactam antibiotics. MbetaLs are synthesized in the bacterial cytoplasm as precursors and are secreted into the periplasm. Here, we report that the biogenesis process of the recently characterized MbetaL GOB-18 demands cooperation between a main chaperone system of the bacterial cytoplasm, DnaK, and the Sec secretion machinery. Using the expression of the complete gob-18 gene from the gram-negative opportunistic pathogen Elizabethkingia meningoseptica in Escherichia coli as a model system, we found that the precursor of this metalloenzyme is secreted by the Sec pathway and reduces cell susceptibility to different beta-lactam antibiotics. Moreover, acting with different J proteins such as cytoplasmic DnaJ and membrane-associated DjlA as cochaperones, DnaK plays an essential role in the cytoplasmic transit of the GOB-18 precursor to the Sec translocon. Our studies also revealed a less relevant role, that of assisting in GOB-18 secretion, for trigger factor, while no significant functions were found for other main cytoplasmic chaperones such as SecB or GroEL/ES. The overall findings indicate that the biogenesis of GOB-18 involves cytoplasmic interaction of the precursor protein mainly with DnaK, secretion by the Sec system, and final folding and incorporation of Zn(II) ions into the bacterial periplasm.

Trigger Factor can antagonize both SecB and DnaK/DnaJ chaperone functions in Escherichia coli

Polypeptides emerging from the ribosome are assisted by a pool of molecular chaperones and targeting factors, which enable them to efficiently partition as cytoplasmic, integral membrane, or exported proteins. In Escherichia coli, the chaperones SecB, Trigger Factor (TF), and DnaK are key players in this process. Here, we report that, as with dnaK or dnaJ mutants, a secB null strain exhibits a strong cold-sensitive (Cs) phenotype. Through suppressor analyses, we found that inactivating mutations in the tig gene encoding TF fully relieve both the Cs phenotype and protein aggregation observed in the absence of SecB. This antagonistic effect of TF depends on its ribosome-binding and chaperone activities but unrelated to its peptidyl-prolyl cis/trans isomerase (PPIase) activity. Furthermore, in contrast to the previously known synergistic action of TF and DnaK/DnaJ above 30 degrees C, a tig null mutation partially suppresses the Cs phenotype exhibited by a compromised DnaK/DnaJ chaperone machine. The antagonistic role of TF is further exemplified by the fact that the secB dnaJ double mutant is viable only in the absence of TF. Finally, we show that, in the absence of TF, more SecA and ribosomes are associated with the inner membrane, suggesting that the presence of TF directly or indirectly interferes with the process of cotranslational protein targeting to the Sec translocon.

Expression and assembly of a functional type IV secretion system elicit extracytoplasmic and cytoplasmic stress responses in Escherichia coli

Conditions perturbing protein homeostasis are known to induce cellular stress responses in prokaryotes and eukaryotes. Here we show for the first time that expression and assembly of a functional type IV secretion (T4S) machinery elicit extracytoplasmic and cytoplasmic stress responses in Escherichia coli. After induction of T4S genes by a nutritional upshift and assembly of functional DNA transporters encoded by plasmid R1-16, host cells activated the CpxAR envelope stress signaling system, as revealed by induction or repression of downstream targets of the CpxR response regulator. Furthermore, we observed elevated transcript levels of cytoplasmic stress genes, such as groESL, with a concomitant increase of sigma(32) protein levels in cells expressing T4S genes. A traA null mutant of plasmid R1-16, which lacks the functional gene encoding the major pilus protein pilin, showed distinctly reduced stress responses. These results corroborated our conclusion that the activation of bacterial stress networks was dependent on the presence of functional T4S machinery. Additionally, we detected increased transcription from the rpoHp(1) promoter in the presence of an active T4S system. Stimulation of rpoHp(1) was dependent on the presence of CpxR, suggesting a hitherto undocumented link between CpxAR and sigma(32)-regulated stress networks.

Recombinant protein folding and misfolding in Escherichia coli

The past 20 years have seen enormous progress in the understanding of the mechanisms used by the enteric bacterium Escherichia coli to promote protein folding, support protein translocation and handle protein misfolding. Insights from these studies have been exploited to tackle the problems of inclusion body formation, proteolytic degradation and disulfide bond generation that have long impeded the production of complex heterologous proteins in a properly folded and biologically active form. The application of this information to industrial processes, together with emerging strategies for creating designer folding modulators and performing glycosylation all but guarantee that E. coli will remain an important host for the production of both commodity and high value added proteins.

The archaeal Sec-dependent protein translocation pathway

Over the past three decades, transport of proteins across cellular membranes has been studied extensively in various model systems. One of the major transport routes, the so-called Sec pathway, is conserved in all domains of life. Very little is known about this pathway in the third domain of life, archaea. The core components of the archaeal, bacterial and eucaryal Sec machinery are similar, although the archaeal components appear more closely related to their eucaryal counterparts. Interestingly, the accessory factors of the translocation machinery are similar to bacterial components, which indicates a unique hybrid nature of the archaeal translocase complex. The mechanism of protein translocation in archaea is completely unknown. Based on genomic sequencing data, the most likely system for archaeal protein translocation is similar to the eucaryal co-translational translocation pathway for protein import into the endoplasmic reticulum, in which a protein is pushed across the translocation channel by the ribosome. However, other models can also be envisaged, such as a bacterial-like system in which a protein is translocated post-translationally with the aid of a motor protein analogous to the bacterial ATPase SecA. This review discusses the different models. Furthermore, an overview is given of some of the other components that may be involved in the protein translocation process, such as those required for protein targeting, folding and post-translational modification.

The SecB chaperone is bifunctional in Serratia marcescens: SecB is involved in the Sec pathway and required for HasA secretion by the ABC transporter

HasA is the secreted hemophore of the heme acquisition system (Has) of Serratia marcescens. It is secreted by a specific ABC transporter apparatus composed of three proteins: HasD, an inner membrane ABC protein; HasE, another inner membrane protein; and HasF, a TolC homolog. Except for HasF, the structural genes of the Has system are encoded by an iron-regulated operon. In previous studies, this secretion system has been reconstituted in Escherichia coli, where it requires the presence of the SecB chaperone, the Sec pathway-dedicated chaperone. We cloned and inactivated the secB gene from S. marcescens. We show that S. marcescens SecB is 93% identical to E. coli SecB and complements the secretion defects of a secB mutant of E. coli for both the Sec and ABC pathways of HasA secretion. In S. marcescens, SecB inactivation affects translocation by the Sec pathway and abolishes HasA secretion. This demonstrates that S. marcescens SecB is the genuine chaperone for HasA secretion in S. marcescens. These results also demonstrate that S. marcescens SecB is bifunctional, as it is involved in two separate secretion pathways. We investigated the effects of secB point mutations in the reconstituted HasA secretion pathway by comparing the translocation of a Sec substrate in various mutants. Two different patterns of SecB residue effects were observed, suggesting that SecB functions may differ for the Sec and ABC pathways.

Identification of a twin-arginine leader-binding protein

The transport and targeting of a number of periplasmic proteins is carried out by the Sec-independent Mtt (also referred to as Tat) protein translocase. Proteins using this translocase have a distinct twin-arginine-containing leader. We hypothesized that specific leader-binding proteins exist to escort proteins to the translocase complex. A fusion was constructed with the twin-arginine leader from dimethyl sulphoxide (DMSO) reductase, subunit DmsA, to the N-terminus of glutathione-S-transferase. This leader fusion was bound to a glutathione affinity column through which an Escherichia coli anaerobic cell-free extract was passed. Proteins that bound to the leader were then separated and identified by N-terminal sequencing, which identified DnaK and a protein originating from the uncharacterized reading frame ynfI. This gene has been designated dmsD based on the findings presented in this paper. DmsD was purified as a His6 fusion and was shown to interact with preprotein forms of DmsA and TorA (trimethyl amine N-oxide reductase). A strain carrying a dmsD knock-out mutation showed a loss of anaerobic growth on glycerol-DMSO medium and reduced growth on glycerol-fumarate medium. This work suggests that DmsD is a twin-arginine leader-binding protein.

Domain-specific spectroscopy of 5-hydroxytryptophan-containing variants of Escherichia coli DnaJ

Tryptophan-containing variants of Escherichia coli DnaJ protein were constructed in order to examine the hypothetical domain structure by fluorescence quenching and denaturant-induced unfolding. Two residues in the J-domain and one in the Gly/Phe-rich region were targeted for replacement and the proteins were expressed in a tryptophan auxotrophic strain in the presence of 5-hydroxytryptophan (5-HW). Fluorescence quenching with iodide of 5-HW in the variant proteins suggests that the Gly/Phe-rich region is more accessible to solvent than the J-domain. This is consistent with the proposal that the Gly/Phe-rich region is unstructured. Unfolding of the 5-HW-containing variants was monitored by fluorescence, and the results showed that the unfolding of the J-domain is cooperative and the unfolding of the Gly/Phe-rich region is not cooperative.

Interaction of Bacillus subtilis CsaA with SecA and precursor proteins

CsaA from the Gram-positive bacterium Bacillus subtilis has been identified previously as a suppressor of the growth and protein-export defect of Escherichia coli secA(Ts) mutants. CsaA has chaperone-like activities in vivo and in vitro. To examine the role of CsaA in protein export in B. subtilis, expression of the csaA gene was repressed. While export of most proteins remained unaffected, export of at least two proteins was significantly reduced upon CsaA depletion. CsaA co-immunoprecipitates and co-purifies with the SecA proteins of E. coli and B. subtilis, and binds the B. subtilis preprotein prePhoB. Purified CsaA stimulates the translocation of prePhoB into E. coli membrane vesicles bearing the B. subtilis translocase, whereas it interferes with the SecB-mediated translocation of proOmpA into membrane vesicles of E. coli. The specific interaction with the SecA translocation ATPase and preproteins suggests that CsaA acts as a chaperone that promotes the export of a subset of preproteins in B. subtilis.

Chaperone-like activities of the CsaA protein of Bacillus subtilis

The growth and protein export defects of Escherichia coli secA51(Ts) strains can be suppressed by the CsaA protein of Bacillus subtilis. The present studies indicate that this effect can be attributed to chaperone-like activities of CsaA. First, CsaA stimulated protein export in secB, groES and dnaJ mutant strains of E. coli. Second, CsaA suppressed the growth defects of dnaK, dnaJ and grpE mutants of E. coli. Third, and most importantly, CsaA exhibited chaperone-like properties by stimulating the reactivation of heat-denatured firefly luciferase in groEL, groES, dnaK and grpE mutant strains of E. coli, and by preventing the aggregation of heat-denatured luciferase in vitro. Thus, it seems that CsaA suppresses the growth and secretion defects of E. coli secA(Ts) strains either by improving the translocation competence of exported pre-proteins, thereby making them better substrates for mutant SecA proteins, or by stimulating the translocation activity of mutant SecA proteins.

SecA: the ubiquitous component of preprotein translocase in prokaryotes

SecA is an obligatory component of the complex hetero-septameric translocase of prokaryotes. It is unique in that it exists as two forms within the holoenzyme; first, as a structural component of the preprotein channel and second, as an ATP-dependent membrane cycling factor facilitating the translocation of a broad class of proteins across the cytoplasmic membrane. While the translocase activity of SecA appears to be functionally conserved, it is not clear whether the mechanisms of regulation of the secA gene are similarly maintained. The recent characterization of an ATP-dependent RNA helicase activity of SecA offers a unique mechanism for SecA to communicate the secretion status of the cell to the appropriate regulatory circuits simply by the unwinding of an appropriate RNA target. Resolution of these two activities through combined biochemical, genetic, and biophysical studies should lead to a better understanding of the role of SecA in bacterial secretion.

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.

Protein targeting to the bacterial cytoplasmic membrane

Proteins that perform their activity within the cytoplasmic membrane or outside this cell boundary must be targeted to the translocation site prior to their insertion and/or translocation. In bacteria, several targeting routes are known; the SecB- and the signal recognition particle-dependent pathways are the best characterized. Recently, evidence for the existence of a third major route, the twin-Arg pathway, was gathered. Proteins that use either one of these three different pathways possess special features that enable their specific interaction with the components of the targeting routes. Such targeting information is often contained in an N-terminal extension, the signal sequence, but can also be found within the mature domain of the targeted protein. Once the nascent chain starts to emerge from the ribosome, competition for the protein between different targeting factors begins. After recognition and binding, the targeting factor delivers the protein to the translocation sites at the cytoplasmic membrane. Only by means of a specific interaction between the targeting component and its receptor is the cargo released for further processing and translocation. This mechanism ensures the high-fidelity targeting of premembrane and membrane proteins to the translocation site.

Defective export in Escherichia coli caused by DsbA'-PhoA hybrid proteins whose DsbA' domain cannot fold into a conformation resistant to periplasmic proteases

The disulfide bond-forming factor DsbA and the alkaline phosphatase are stable in the Escherichia coli periplasmic space and can be overproduced without significant perturbation of the cell's physiology. By contrast, DsbA'-PhoA hybrid proteins resulting from TnphoA insertions into different regions of a plasmid-borne dsbA gene could become toxic (lethal) to bacteria. Toxicity was concomitant with an impairment of some step of the export mechanism and depended on at least three parameters, i.e., (i) the rate of expression of the hybrid protein, (ii) the ability of the amino-terminal DsbA' domain of the hybrid protein to fold into a protease-resistant conformation in the periplasmic space, and (iii) the activity of the DegP periplasmic protease. Even under viable conditions of low expression, DsbA' folding-deficient hybrid proteins accumulated more than the folding-proficient ones in the insoluble material and this was aggravated in a strain lacking the DegP protease. When production was more elevated, the folding-deficient hybrid proteins became lethal, but only in strains lacking the DegP activity, while the folding-proficient ones were not. Under conditions of very high production by degP+ or degP strains, both types of hybrid proteins accumulated as insoluble preproteins. Meanwhile, the export machinery was dramatically handicapped and the cells lost viability. However, the folding-deficient hybrid proteins had a higher killing efficiency than the folding-proficient ones. Free DsbA'-truncated polypeptides, although not toxic, were processed more slowly when they could not fold into a protease-resistant form in the periplasmic space. This provides indications in E. coli for a direct or indirect influence of the folding of a protein in the periplasmic environment on export efficiency.

Protein targeting and translocation; a comparative survey

The last few years has seen enormous progress in understanding of protein targeting and translocation across biological membranes. Many of the key molecules involved have been identified, isolated, and the corresponding genes cloned, opening up the way for detailed analysis of the structure and function of these molecular machines. It has become clear that the protein translocation machinery of the endoplasmic reticulum is very closely related to that of bacteria, and probably represents an ancient solution to the problem of how to get a protein across a membrane. One of the thylakoid translocation systems looks as if it will also be very similar, and probably represents a pathway inherited from the ancestral endosymbiont. It is interesting that, so far, there is a perfect correlation between thylakoid proteins which are present in photosynthetic prokaryotes and those which use the sec pathway in chloroplasts; conversely, OE16 and 23 which use the delta pH pathway are not found in cyanobacteria. To date, no Sec-related proteins have been found in mitochondria, although these organelles also arose as a result of endosymbiotic events. However, virtually nothing is known about the insertion of mitochondrially encoded proteins into the inner membrane. Is the inner membrane machinery which translocates cytoplasmically synthesized proteins capable of operating in reverse to export proteins from the matrix, or is there a separate system? Alternatively, do membrane proteins encoded by mitochondrial DNA insert independently of accessory proteins? Unlike nuclear-encoded proteins, proteins encoded by mtDNA are not faced with a choice of membrane and, in principle, could simply partition into the inner membrane. The ancestors of mitochondria almost certainly had a Sec system; has this been lost along with many of the proteins once encoded in the endosymbiont genome, or is there still such a system waiting to be discovered? The answer to this question may also shed light on the controversy concerning the sorting of the inter-membrane space proteins cytochrome c1 and cytochrome b2, as the conservative-sorting hypothesis would predict re-export of matrix intermediates via an ancestral (possibly Sec-type) pathway. Whereas the ER and bacterial systems clearly share homologous proteins, the protein import machineries of mitochondria and chloroplasts appear to be analogous rather than homologous. In both cases, import occurs through contact sites and there are separate translocation complexes in each membrane, however, with the exception of some of the chaperone molecules, the individual protein components do not appear to be related. Their similarities may be a case of convergent rather than divergent evolution, and may reflect what appear to be common requirements for translocation, namely unfolding, a receptor, a pore complex and refolding. There are also important differences. Translocation across the mitochondrial inner membrane is absolutely dependent upon delta psi, but no GTP requirement has been identified. In chloroplasts the reverse is the case. The roles of delta psi and GTP, respectively, remain uncertain, but it is tempting to speculate that they may play a role in regulating the import process, perhaps by controlling the assembly of a functional translocation complex. In the case of peroxisomes, much still remains to be learned. Many genes involved in peroxisome biogenesis have been identified but, in most cases, the biochemical function remains to be elucidated. In this respect, understanding of peroxisome biogenesis is at a similar stage to that of the ER 10 years ago. The coming together of genetic and biochemical approaches, as with the other organelles, should provide many of the answers.

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.

Combined effects of the signal sequence and the major chaperone proteins on the export of human cytokines in Escherichia coli

We have studied the export of two human proteins in the course of their production in Escherichia coli. The coding sequences of the granulocyte-macrophage colony-stimulating factor and of interleukin 13 were fused to those of two synthetic signal sequences to direct the human proteins to the bacterial periplasm. We found that the total amount of protein varies with the signal peptide-cytokine combination, as does the fraction of it that is soluble in a periplasmic extract. The possibility that the major chaperone proteins such as SecB and the GroEL-GroES and DnaK-DnaJ pairs are limiting factors for the export was tested by overexpressing one or the other of these chaperones concomitantly with the heterologous protein. The GroEL-GroES chaperone pair had no effect on protein production. Overproduction of SecB or DnaK plus DnaJ resulted in a marked increase of the quantity of human proteins in the periplasmic fraction, but this increase depends on the signal peptide-heterologous protein-chaperone association involved.

Demonstration in vivo that interaction of maltose-binding protein with SecB is determined by a kinetic partitioning

An early step in the export of maltose-binding protein to the periplasm is interaction with the molecular chaperone SecB. We demonstrate that binding to SecB in vivo is determined by a kinetic partitioning between the folding of maltose-binding protein to its native state and its association with SecB. A complex of SecB and a species of maltose-binding protein that folds slowly is shown to be longer-lived than a complex of the wild-type maltose-binding protein and SecB. In addition, we show that incomplete nascent chains, which are unable to fold, remain complexed with SecB.

Signal recognition particle (SRP), a ubiquitous initiator of protein translocation

In higher eukaryotes, most secretory and membrane proteins are synthesised by ribosomes which are attached to the membrane of the rough endoplasmic reticulum (RER). This allows the proteins to be translocated across that membrane already during their synthesis. The ribosomes are directed to the RER membrane by a cytoplasmic ribonucleoprotein particle, the signal recognition particle (SRP). SRP fulfills its task by virtue of three distinguishable activities: the binding of a signal sequence which, being part of the nascent polypeptide to be translocated, is exposed on the surface of a translating ribosome; the retardation of any further elongation; and the SRP-receptor-mediated binding of the complex of ribosome, nascent polypeptide and SRP to the RER membrane which results in the detachment of SRP from the signal sequence and the ribosome and the insertion of the nascent polypeptide into the membrane. Evidence is accumulating that SRP is not restricted to eukaryotes: SRP-related particles and SRP-receptor-related molecules are found ubiquitously and may function in protein translocation in every living organism. This review focuses on the mammalian SRP. A brief discussion of its overall structure is followed by a detailed description of the structures of its RNA and protein constituents and the requirements for their assembly into the particle. Homologues of SRP components from organisms other than mammals are mentioned to emphasize the components' conserved or less conserved features. Subsequently, the functions of each of the SRP constituents are discussed. This sets the stage for a presentation of a model for the mechanism by which SRP cyclically assembles and disassembles with translating ribosomes and the RER membrane. It may be expected that similar mechanisms are used by SRP homologues in organisms other than mammals. However, the mammalian SRP-mediated translocation mechanism may not be conserved in its entirety in organisms like Escherichia coli whose SRP lack components required for the function of the mammalian SRP. Possible translocation pathways involving the rudimentary SRP are discussed in view of the existence of alternative, chaperone-mediated translocation pathways with which they may intersect. The concluding two sections deal with open questions in two areas of SRP research. One formulates basic questions regarding the little-investigated biogenesis of SRP. The other gives an outlook over the insights into the mechanisms of each of the known activities of the SRP that are to be expected in the short and medium-term future.

Mammalian and Escherichia coli signal recognition particles

Recent evidence from both biochemical and genetic studies indicates that protein targeting to the prokaryotic cytoplasmic membrane and the eukaryotic endoplasmic reticulum membrane may have more in common than previously thought. A ribonucleoprotein particle was identified in Escherichia coli that consists of at least one protein (P48 or Ffh) and one RNA molecule (4.5S RNA), both of which exhibit strong sequence similarity with constituents of the mammalian signal recognition particle (SRP). Like the mammalian SRP, the E. coli SRP binds specifically to the signal sequence of presecretory proteins. Depletion of either P48 or 4.5S RNA affects translation and results in the accumulation of precursors of several secreted proteins. This review discusses the recent studies and speculates on the position of the SRP in the complex network of protein interactions involved in translation and membrane targeting in E. coli.

Accumulation of secretory protein precursors in Escherichia coli induces the heat shock response

The accumulation of secretory protein precursors, caused either by mutations in secB or secA or by the overproduction of export-defective proteins, results in a two- to fivefold increase in the synthesis of heat shock proteins. In such strains, sigma 32, the alternative sigma factor responsible for transcription of the heat shock genes, is stabilized. The resultant increase in the level of sigma 32 leads to increased transcription of heat shock genes and increased synthesis of heat shock proteins. We have also found that although a secB null mutant does not grow on rich medium at a temperature range of 30 to 42 degrees C, it does grow at 44 degrees C. In addition, we found that a secB null mutant exhibits greater thermotolerance than the wild-type parental strain. Elevated levels of heat shock proteins, as well as some other non-heat shock proteins, may account for the partial heat resistance of a SecB-lacking strain.

The roles of signal peptide and mature protein in RNase (barnase) export from Bacillus subtilis

Barnase, an extracellular RNAse from Bacillus amyloliquefaciens is secreted post-translationally from B. subtilis. The rate of secretion of barnase from B. subtilis was improved by replacement of the barnase signal peptide with a heterologous signal peptide. However, the barnase signal peptide exported Escherichia coli alkaline phosphatase faster than mature barnase. Heat shock of B. subtilis cells did not significantly alter the export of barnase using the barnase signal peptide. The slow rate of export of barnase from B. subtilis is due to both the signal peptide and the mature protein sequence rather than either alone.

Modulation of the heat shock response by one-carbon metabolism in Escherichia coli

A genetic screen designed to isolate mutants of Escherichia coli W3110 altered in the ability to induce the heat shock response identified a strain unable to induce the heat shock proteins in a rich, defined medium lacking methionine after exposure to 2,4-dinitrophenol. This strain also grew slowly at 28 degrees C and linearly at 42 degrees C in this medium. The abnormal induction of the heat shock proteins and abnormal growth at both high and low temperatures were reversed when methionine was included in the growth medium. The mutation responsible for these phenotypes mapped to the glyA gene, a biosynthetic gene encoding the enzyme that converts serine and tetrahydrofolate to glycine and 5,10-methylenetetrahydrofolate. This reaction is the major source of glycine and one-carbon units in the cell. Because fixed one-carbon units, in the form of methionine, allowed mutant cells to induce the heat shock response after exposure to 2,4-dinitrophenol, a one-carbon restriction may be responsible for the phenotypes described above.

A mutation of Escherichia coli SecA protein that partially compensates for the absence of SecB

The Escherichia coli SecB protein is a cytosolic chaperone protein that is required for rapid export of a subset of exported proteins. To aid in elucidation of the activities of SecB that contribute to rapid export kinetics, mutations that partially suppressed the export defect caused by the absence of SecB were selected. One of these mutations improves protein export in the absence of SecB and is the result of a duplication of SecA coding sequences, leading to the synthesis of a large, in-frame fusion protein. Unexpectedly, this mutation conferred a second phenotype. The secA mutation exacerbated the defective protein export caused by point mutations in the signal sequence of pre-maltose-binding protein. One explanation for these results is that the mutant SecA protein has sustained a duplication of its binding site(s) for exported protein precursors so that the mutant SecA is altered in its interaction with precursor molecules.

The Cs sec mutants of Escherichia coli reflect the cold sensitivity of protein export itself

We have found that temperature can have a striking effect upon protein export in Escherichia coli, suggesting that there is a cold-sensitive step in the protein export pathway. Cs mutations comprise the largest class of mutations affecting the membrane-localized Sec proteins SecD, SecE, SecF and SecY. Although some of these mutations could encode cold-labile proteins, this is unlikely to account for the Cs phenotype of most export mutants, as mutations which simply produce lower amounts of SecE protein have the same phenotype. Certain signal sequence mutations affecting maltose binding protein are also cold sensitive for export. These effects appear to arise by a specific interaction of cold with certain export defects. We believe that the Cs sec mutations are representative of a large class of conditional lethal mutations, whose conditional phenotype reflects an underlying thermal sensitivity of the process in which they are involved.

The complete general secretory pathway in gram-negative bacteria

The unifying feature of all proteins that are transported out of the cytoplasm of gram-negative bacteria by the general secretory pathway (GSP) is the presence of a long stretch of predominantly hydrophobic amino acids, the signal sequence. The interaction between signal sequence-bearing proteins and the cytoplasmic membrane may be a spontaneous event driven by the electrochemical energy potential across the cytoplasmic membrane, leading to membrane integration. The translocation of large, hydrophilic polypeptide segments to the periplasmic side of this membrane almost always requires at least six different proteins encoded by the sec genes and is dependent on both ATP hydrolysis and the electrochemical energy potential. Signal peptidases process precursors with a single, amino-terminal signal sequence, allowing them to be released into the periplasm, where they may remain or whence they may be inserted into the outer membrane. Selected proteins may also be transported across this membrane for assembly into cell surface appendages or for release into the extracellular medium. Many bacteria secrete a variety of structurally different proteins by a common pathway, referred to here as the main terminal branch of the GSP. This recently discovered branch pathway comprises at least 14 gene products. Other, simpler terminal branches of the GSP are also used by gram-negative bacteria to secrete a more limited range of extracellular proteins.

YDJ1p facilitates polypeptide translocation across different intracellular membranes by a conserved mechanism

The role of S. cerevisiae YDJ1 protein (YDJ1p) in polypeptide translocation across membranes has been examined. A conditional ydj1 mutant strain (ydj1-151TS) is defective for import of several polypeptides into mitochondria and alpha factor into the endoplasmic reticulum at 37 degrees C. These defects are suppressed by E. coli dnaJ or overexpression of S. cerevisiae SIS1 proteins. A different ydj1 mutant, which cannot be farnesylated (ydj1-S406), displays similar transport defects to the ydj1-151 strain. Furthermore, the ability of purified ydj1-151p to stimulate the ATPase activity of hsp70SSA1 was greatly diminished compared with the wild-type protein. Together, these data suggest that YDJ1p functions in polypeptide translocation in a conserved manner, probably acting at organelle membranes and in association with hsp70 proteins.

Protein export in Escherichia coli

The export of protein from Escherichia coli has been studied by genetic, biochemical and biophysical techniques. These studies have defined a number of steps in the export pathway and have identified the cellular components required for the translocation process. New information is presented on the function of some of these components.

DnaK and DnaJ heat shock proteins participate in protein export in Escherichia coli

In Escherichia coli secreted proteins must be maintained in an export-competent state before translocation across the cytoplasmic membrane. This function is carried out by a group of proteins called chaperones. SecB is the major chaperone that interacts with precursor proteins before their secretion. We report results indicating that the DnaK and DnaJ heat shock proteins are also involved in the export of several proteins, most likely by acting as their chaperones. Translocation of alkaline phosphatase, a SecB-independent protein, was inhibited in dnaK- and dnaJ- mutant strains, suggesting that export of this protein probably involves DnaK and DnaJ. In addition, DnaK and DnaJ play a critical role in strains lacking SecB. They are required both for viability and for the residual processing of the SecB-dependent proteins LamB and maltose-binding protein (MBP) seen in secB null strains. Furthermore, overproduction of DnaK and DnaJ permits strains lacking SecB to grow in rich medium and accelerates the processing of LamB and MBP. These results suggest that under conditions where SecB becomes limiting, DnaK and DnaJ probably substitute for SecB and facilitate protein export. This provides the cell with a mechanism to overcome a temporary imbalance in the secretion process caused by an abrupt expansion in the pool of precursor proteins.

Interaction of the heat shock protein GroEL of Escherichia coli with single-stranded DNA-binding protein: suppression of ssb-113 by groEL46

Previous studies from our laboratory have shown that an allele of the heat shock protein GroEL (groEL411) is able to specifically suppress some of the physiological defects of the single-stranded DNA-binding protein mutation ssb-1. A search for additional alleles of the groE genes which may act as suppressors for ssb mutations has led to the identification of groEL46 as a specific suppressor of ssb-113. It has very little or no effect on ssb-1 or ssb-3. All of the physiological defects of ssb-113, including temperature-sensitive growth, temperature-sensitive DNA synthesis, sensitivity to UV irradiation, methyl methanesulfonate, and bleomycin, and reduced recombinational capacity, are restored to wild-type levels. The ssb-113 allele, however, is unable to restore sensitivity of groEL46 cells to phage lambda. The mechanism of suppression of ssb-113 by groEL46 appears to differ from that of ssb-1 by groEL411. The data suggest that GroEL may interact with single-stranded DNA-binding protein in more than one domain.

Characterization of the groEL-like genes in Streptomyces albus

Three GroEL-like heat shock proteins (HSP56, HSP58, and HSP18) have been observed in Streptomyces albus (G. Guglielmi, P. Mazodier, C. J. Thompson, and J. Davies, J. Bacteriol. 173:7374-7381, 1991). Here we report the cloning and complete nucleotide sequence of groEL1, which encodes HSP18 and HSP58, and groEL2, which encodes HSP56. Both nucleotide sequences predicted proteins of 56,680 Da that were 70% identical. The 5' nucleotide sequence of groEL1 coded for a protein corresponding to HSP18 that may be a processed gene product. At least two groEL-like genes were present in all 12 Streptomyces species tested; they were not closely linked in the genome. groEL1, but not groEL2, was adjacent to a groES-like gene.

Targeting and assembly of an oligomeric bacterial enterotoxoid in the endoplasmic reticulum of Saccharomyces cerevisiae

A hybrid protein consisting of the Escherichia coli lipoprotein signal sequence attached to the mature sequence of the B subunit of heat-labile enterotoxin (Lipo-EtxB) was expressed in yeast and E. coli. Analyses of cell lysates from Saccharomyces cerevisiae and E. coli expressing the protein revealed that both organisms were able to assemble Lipo-EtxB into oligomers that were (i) stable in the presence of sodium dodecyl sulphate, (ii) resistant to proteinase K degradation, and (iii) able to bind to GM1-ganglioside receptors. Each of these properties are characteristic of the wild-type B subunit pentamer produced in E. coli. Assembly of Lipo-EtxB was found to be unaffected in a sec18 mutant of S. cerevisiae, which possesses a temperature-sensitive defect in protein transport from the endoplasmic reticulum (ER) to the Golgi apparatus, but was found not to assemble in a sec53 mutant, which causes the misfolding of proteins targeted to the ER. A kar2-1 mutation with a defect in the yeast homologue of BiP caused an 18-fold reduction in Lipo-EtxB assembly at the non-permissive temperature in S. cerevisiae. However, introduction of the wild-type KAR2 gene on a plasmid into the kar2-1 mutant completely suppressed the inhibition of Lipo-EtxB assembly. This provides the first evidence that KAR2 facilitates the assembly of an oligomeric protein in yeast and thus implicates KAR2 as a 'molecular chaperone'. The possible mechanisms of enterotoxoid assembly in E. coli and S. cerevisiae are discussed.