Molecular guardians for newborn proteins: ribosome-associated chaperones and their role in protein folding.

A central dogma in biology is the conversion of genetic information into active proteins. The biosynthesis of proteins by ribosomes and the subsequent folding of newly made proteins represent the last crucial steps in this process. To guarantee the correct folding of newly made proteins, a complex chaperone network is required in all cells. In concert with ongoing protein biosynthesis, ribosome-associated factors can interact directly with emerging nascent polypeptides to protect them from degradation or aggregation, to promote folding into their native structure, or to otherwise contribute to their folding program. Eukaryotic cells possess two major ribosome-associated systems, an Hsp70/Hsp40-based chaperone system and the functionally enigmatic NAC complex, whereas prokaryotes employ the Trigger Factor chaperone. Recent structural insights into Trigger Factor reveal an intricate cradle-like structure that, together with the exit site of the ribosome, forms a protected environment for the folding of newly synthesized proteins.

Low temperature of GroEL/ES overproduction permits growth of Escherichia coli cells lacking trigger factor DnaK.

Escherichia coli trigger factor (TF) and DnaK cooperate in the folding of newly synthesized proteins. The combined deletion of the TF-encoding tig gene and the dnaK gene causes protein aggregation and synthetic lethality at 30 degrees C. Here we show that the synthetic lethality of deltatigdeltadnaK52 cells is abrogated either by growth below 30 degrees C or by overproduction of GroEL/GroES. At 23 degrees C deltatigdeltadnaK52 cells were viable and showed only minor protein aggregation. Overproduction of GroEL/GroES, but not of other chaperones, restored growth of deltatigdeltadnaK52 cells at 30 degrees C and suppressed protein aggregation including proteins >/= 60 kDa, which normally require TF and DnaK for folding. GroEL/GroES thus influences the folding of proteins previously identified as DnaK/TF substrates.

Functional dissection of Escherichia coli trigger factor: unraveling the function of individual domains.

In Escherichia coli, the ribosome-associated chaperone Trigger Factor (TF) promotes the folding of newly synthesized cytosolic proteins. TF is composed of three domains: an N-terminal domain (N), which mediates ribosome binding; a central domain (P), which has peptidyl-prolyl cis/trans isomerase activity and is involved in substrate binding in vitro; and a C-terminal domain (C) with unknown function. We investigated the contributions of individual domains (N, P, and C) or domain combinations (NP, PC, and NC) to the chaperone activity of TF in vivo and in vitro. All fragments comprising the N domain (N, NP, NC) complemented the synthetic lethality of Deltatig DeltadnaK in cells lacking TF and DnaK, prevented protein aggregation in these cells, and cross-linked to nascent polypeptides in vitro. However, DeltatigDeltadnaK cells expressing the N domain alone grew more slowly and showed less viability than DeltatigDeltadnaK cells synthesizing either NP, NC, or full-length TF, indicating beneficial contributions of the P and C domains to TF's chaperone activity. In an in vitro system with purified components, none of the TF fragments assisted the refolding of denatured d-glyceraldehyde-3-phosphate dehydrogenase in a manner comparable to that of wild-type TF, suggesting that the observed chaperone activity of TF fragments in vivo is dependent on their localization at the ribosome. These results indicate that the N domain, in addition to its function to promote binding to the ribosome, has a chaperone activity per se and is sufficient to substitute for TF in vivo.

Low temperature or GroEL/ES overproduction permits growth of Escherichia coli cells lacking trigger factor and DnaK.

Escherichia coli trigger factor (TF) and DnaK cooperate in the folding of newly synthesized proteins. The combined deletion of the TF-encoding tig gene and the dnaK gene causes protein aggregation and synthetic lethality at 30 degrees C. Here we show that the synthetic lethality of DeltatigDeltadnaK52 cells is abrogated either by growth below 30 degrees C or by overproduction of GroEL/GroES. At 23 degrees C DeltatigDeltadnaK52 cells were viable and showed only minor protein aggregation. Overproduction of GroEL/GroES, but not of other chaperones, restored growth of DeltatigDeltadnaK52 cells at 30 degrees C and suppressed protein aggregation including proteins >/=60 kDa, which normally require TF and DnaK for folding. GroEL/GroES thus influences the folding of proteins previously identified as DnaK/TF substrates.

Essential Bacillus subtilis genes.

To estimate the minimal gene set required to sustain bacterial life in nutritious conditions, we carried out a systematic inactivation of Bacillus subtilis genes. Among approximately 4,100 genes of the organism, only 192 were shown to be indispensable by this or previous work. Another 79 genes were predicted to be essential. The vast majority of essential genes were categorized in relatively few domains of cell metabolism, with about half involved in information processing, one-fifth involved in the synthesis of cell envelope and the determination of cell shape and division, and one-tenth related to cell energetics. Only 4% of essential genes encode unknown functions. Most essential genes are present throughout a wide range of Bacteria, and almost 70% can also be found in Archaea and Eucarya. However, essential genes related to cell envelope, shape, division, and respiration tend to be lost from bacteria with small genomes. Unexpectedly, most genes involved in the Embden-Meyerhof-Parnas pathway are essential. Identification of unknown and unexpected essential genes opens research avenues to better understanding of processes that sustain bacterial life.

Binding specificity of Escherichia coli trigger factor.

The ribosome-associated chaperone trigger factor (TF) assists the folding of newly synthesized cytosolic proteins in Escherichia coli. Here, we determined the substrate specificity of TF by examining its binding to 2842 membrane-coupled 13meric peptides. The binding motif of TF was identified as a stretch of eight amino acids, enriched in basic and aromatic residues and with a positive net charge. Fluorescence spectroscopy verified that TF exhibited a comparable substrate specificity for peptides in solution. The affinity to peptides in solution was low, indicating that TF requires ribosome association to create high local concentrations of nascent polypeptide substrates for productive interaction in vivo. Binding to membrane-coupled peptides occurred through the central peptidyl-prolyl-cis/trans isomerase (PPIase) domain of TF, however, independently of prolyl residues. Crosslinking experiments showed that a TF fragment containing the PPIase domain linked to the ribosome via the N-terminal domain is sufficient for interaction with nascent polypeptide substrates. Homology modeling of the PPIase domain revealed a conserved FKBP(FK506-binding protein)-like binding pocket composed of exposed aromatic residues embedded in a groove with negative surface charge. The features of this groove complement well the determined substrate specificity of TF. Moreover, a mutation (E178V) in this putative substrate binding groove known to enhance PPIase activity also enhanced TF's association with a prolyl-free model peptide in solution and with nascent polypeptides. This result suggests that both prolyl-independent binding of peptide substrates and peptidyl-prolyl isomerization involve the same binding site.

Functional dissection of trigger factor and DnaK: interactions with nascent polypeptides and thermally denatured proteins.

In Escherichia coli, the ribosome-associated Trigger Factor (TF) cooperates with the DnaK system in the folding of newly synthesized cytosolic polypeptides. Here we investigated the functional relationship of TF and DnaK by comparing various functional properties of both chaperones. First, we analyzed the ability of TF and DnaK to associate with nascent polypeptides and full-length proteins released from the ribosome. Toward this end, we established an E. coli based transcription/translation system containing physiological ratios of TF, DnaK and ribosomes. In this system, TF can be crosslinked to nascent polypeptides of sigma32. No TF crosslink was found to full-length sigma32, which is known to be a DnaK substrate. In contrast, DnaK crosslinked to both nascent and full-length sigma32. DnaK crosslinks critically depended on the type of chemical crosslinker. Crosslinks represent specific substrate-chaperone interactions since they relied on the association of the nascent polypeptides with the substrate binding pocket of DnaK. While DnaK is known to be the major chaperone to prevent protein aggregation under heat shock conditions, we found that TF did not prevent aggregation of thermally unfolded proteins in vitro and was not able to complement the heat-sensitive phenotype of a deltadnaK52 mutant in vivo. These data indicate that TF and DnaK show strong differences in their ability to prevent aggregation of denatured proteins and to associate with native like substrates, but share the ability to associate with nascent polypeptides.

Trigger factor and DnaK cooperate in folding of newly synthesized proteins.

The role of molecular chaperones in assisting the folding of newly synthesized proteins in the cytosol is poorly understood. In Escherichia coli, GroEL assists folding of only a minority of proteins and the Hsp70 homologue DnaK is not essential for protein folding or cell viability at intermediate growth temperatures. The major protein associated with nascent polypeptides is ribosome-bound trigger factor, which displays chaperone and prolyl isomerase activities in vitro. Here we show that delta tig::kan mutants lacking trigger factor have no defects in growth or protein folding. However, combined delta tig::kan and delta dnaK mutations cause synthetic lethality. Depletion of DnaK in the delta tig::kan mutant results in massive aggregation of cytosolic proteins. In delta tig::kan cells, an increased amount of newly synthesized proteins associated transiently with DnaK. These findings show in vivo activity for a ribosome-associated chaperone, trigger factor, in general protein folding, and functional cooperation of this protein with a cytosolic Hsp70. Trigger factor and DnaK cooperate to promote proper folding of a variety of E. coli proteins, but neither is essential for folding and viability at intermediate growth temperatures.

The amino-terminal 118 amino acids of Escherichia coli trigger factor constitute a domain that is necessary and sufficient for binding to ribosomes.

Escherichia coli trigger factor has prolyl-isomerase and chaperone activities and associates with nascent polypeptide chains. Trigger factor has a binding site on ribosomes, which is a prerequisite for its efficient association with nascent chains and its proposed function as a cotranslational folding catalyst. We set out to identify the domain of trigger factor that mediates ribosome binding. Of a series of recombinant fragments, the amino-terminal fragments, TF (1-144) and TF (1-247), cofractionated with ribosomes from cell extracts and rebound to isolated ribosomes in vitro. They competed efficiently with full-length trigger factor for stoichiometric binding to a single site on the large ribosomal subunit. However, TF (1-144) and TF (1-247) differed from full-length trigger factor in that their association with ribosomes was not strengthened by the presence of nascent chains, indicating a role for carboxyl-terminal trigger factor segment in sensing the translational status. The domain responsible for ribosome binding was further investigated by limited proteolysis of recombinant fragments. A stable domain comprising the amino-terminal 118 residues was identified that was still capable of ribosome binding and thus represents a novel structural and functional element of trigger factor.

The ftsH gene of Bacillus subtilis is involved in major cellular processes such as sporulation, stress adaptation and secretion.

The ftsH gene of Bacillus subtilis has been identified as a general stress gene which is transiently induced after thermal or osmotic upshift. The FtsH protein exhibits 70.1% homology to FtsH of Escherichia coli which constitutes an essential ATP- and Zn(2+)-dependent protease anchored in the cytoplasmic membrane via two N-terminal transmembrane domains. This paper describes the isolation and functional characterization of an ftsH null mutant which was obtained by integration of a cat-cassette near the 5' end of ftsH, thereby preventing the synthesis of FtsH protein. In contrast to the situation in E. coli, ftsH is dispensable in B. subtilis but results in a pleiotropic phenotype. While the mutant cells grew mostly as large filaments under physiological conditions, they turned out to be extremely sensitive to heat and salt stress. Although ftsH is necessary for adaptation to heat, it is not involved in the regulation of the heat-shock response. The induction profiles of representative genes of the CIRCE and sigma-B regulon and class III heat-shock genes ion and clpC were identical in the wild type and the ftsH null mutant. Furthermore, the ftsH knockout strain was unable to sporulate, and this failure was probably due to the absence of Spo0A protein which is essential for entry into the sporulation programme. In addition, secretion of bulk exoproteins was severely impaired in the ftsH null mutant after entry into stationary phase. The alpha-amylase and subtilisin activity in the supernatant was specifically tested. Whereas the activity of alpha-amylase increased after entry into stationary phase in both the wild type and the ftsH mutant strain, that of subtilisin encoded by aprE was prevented at the level of transcription in the mutant. Most of these results can be explained by the failure to synthesize appropriate amounts of Spo0A protein in the ftsH null mutant and point to ftsH as a developmental checkpoint.

The ftsH gene of Bacillus subtilis is transiently induced after osmotic and temperature upshift.

The ftsH gene of Bacillus subtilis has been identified as a salt-sensitive insertion mutation in strain UG1. Here, we show that UG1 has an insertion near the 3' end of ftsH. The salt sensitivity of this mutant was caused by reduction of ftsH mRNA levels by the synthesis of an artificial antisense RNA originating at a promoter located within the insertion and reading backwards into the ftsH gene. The salt-sensitive phenotype could be overcome by deleting the promoter from which the antisense RNA was transcribed. A physiological analysis of the isogenic wild-type strain in minimal medium revealed unimpaired growth at up to 1 M NaCl, and growth above 1.2 M NaCl was observed only after addition of the osmoprotectant proline or glycine betaine. In contrast, growth of strain UG1 was reduced at a salt concentration above 0.2 M, which could be rescued by the two compatible solutes already mentioned and also by trehalose. Primer extension revealed one potential transcription start site downstream of a putative vegetative promoter, which was activated after osmotic or temperature upshift. Northern (RNA blot) experiments led to the detection of a 2.1-kb transcript, suggesting that ftsH is monocistronic. A transcriptional fusion between ftsH and the gus reporter gene exhibited a twofold increase in beta-glucuronidase activity after osmotic upshift. To further confirm the need for an enhanced level of FtsH protein after osmotic upshift, the promoter was replaced by the sucrose-inducible promoter PsacB. Whereas this mutant strain could grow in the absence of inducer in LB medium, it stopped growth immediately after addition of 1.1 M NaCl. We conclude that an increased amount of FtsH protein is essential for B. subtilis to cope with an increase in osmolarity or temperature.