Elke Deuerling

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 Δtig::kan mutants lacking trigger factor have no defects in growth or protein folding. However, combined Δtig::kan and ΔdnaK mutations cause synthetic lethality. Depletion of DnaK in the Δtig::kan mutant results in massive aggregation of cytosolic proteins. In Δtig::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.

Getting Newly Synthesized Proteins into Shape

Recent progress made in the analysis of in vivo folding of cytosolic proteins suggests that folding of cytosolic proteins occurs via multiple chaperone-assisted, as well as unassisted pathways. In the case of individual proteins, certain pathways may be highly favored. But, the cellular folding machinery also shows significant redundancy and flexibility, resulting in a variable network of folding pathways having alternative routes and backup systems.‡To whom correspondence should be addressed (e-mail: ecraig@facstaff.wisc.edu [E. A. C.], bukau@sun2.ruf.uni-freiburg.de [B. B.]).

Trigger Factor in Complex with the Ribosome Forms a Molecular Cradle for Nascent Proteins

During protein biosynthesis, nascent polypeptide chains that emerge from the ribosomal exit tunnel encounter ribosome-associated chaperones, which assist their folding to the native state. Here we present a 2.7 Å crystal structure of Escherichia coli trigger factor, the best-characterized chaperone of this type, together with the structure of its ribosome-binding domain in complex with the Haloarcula marismortui large ribosomal subunit. Trigger factor adopts a unique conformation resembling a crouching dragon with separated domains forming the amino-terminal ribosome-binding ‘tail’, the peptidyl-prolyl isomerase ‘head’, the carboxy-terminal ‘arms’ and connecting regions building up the ‘back’. From its attachment point on the ribosome, trigger factor projects the extended domains over the exit of the ribosomal tunnel, creating a protected folding space where nascent polypeptides may be shielded from proteases and aggregation. This study sheds new light on our understanding of co-translational protein folding, and suggests an unexpected mechanism of action for ribosome-associated chaperones.

Small heat shock proteins, ClpB and the DnaK system form a functional triade in reversing protein aggregation.

Small heat shock proteins (sHsps) can efficiently prevent the aggregation of unfolded proteins in vitro. However, how this in vitro activity translates to function in vivo is poorly understood. We demonstrate that sHsps of Escherichia coli, IbpA and IbpB, co‐operate with ClpB and the DnaK system in vitro and in vivo, forming a functional triade of chaperones. IbpA/IbpB and ClpB support independently and co‐operatively the DnaK system in reversing protein aggregation. A ΔibpABΔclpB double mutant exhibits strongly increased protein aggregation at 42°C compared with the single mutants. sHsp and ClpB function become essential for cell viability at 37°C if DnaK levels are reduced. The DnaK requirement for growth is increasingly higher for ΔibpAB, ΔclpB, and the double ΔibpABΔclpB mutant cells, establishing the positions of sHsps and ClpB in this chaperone triade.

L23 protein functions as a chaperone docking site on the ribosome

During translation, the first encounter of nascent polypeptides is with the ribosome-associated chaperones that assist the folding process—a principle that seems to be conserved in evolution. In Escherichia coli, the ribosome-bound Trigger Factor chaperones the folding of cytosolic proteins by interacting with nascent polypeptides. Here we identify a ribosome-binding motif in the amino-terminal domain of Trigger Factor. We also show the formation of crosslinked products between Trigger Factor and two adjacent ribosomal proteins, L23 and L29, which are located at the exit of the peptide tunnel in the ribosome. L23 is essential for the growth of E. coli and the association of Trigger Factor with the ribosome, whereas L29 is dispensable in both processes. Mutation of an exposed glutamate in L23 prevents Trigger Factor from interacting with ribosomes and nascent chains, and causes protein aggregation and conditional lethality in cells that lack the protein repair function of the DnaK chaperone. Purified L23 also interacts specifically with Trigger Factor in vitro. We conclude that essential L23 provides a chaperone docking site on ribosomes that directly links protein biosynthesis with chaperone-assisted protein folding.

Chaperone-based procedure to increase yields of soluble recombinant proteins produced in E. coli

BackgroundThe overproduction of recombinant proteins in host cells often leads to their misfolding and aggregation. Previous attempts to increase the solubility of recombinant proteins by co-overproduction of individual chaperones were only partially successful. We now assessed the effects of combined overproduction of the functionally cooperating chaperone network of the E. coli cytosol on the solubility of recombinant proteins.ResultsA two-step procedure was found to show the strongest enhancement of solubility. In a first step, the four chaperone systems GroEL/GroES, DnaK/DnaJ/GrpE, ClpB and the small HSPs IbpA/IbpB, were coordinately co-overproduced with recombinant proteins to optimize de novo folding. In a second step, protein biosynthesis was inhibited to permit chaperone mediated refolding of misfolded and aggregated proteins in vivo. This novel strategy increased the solubility of 70% of 64 different heterologous proteins tested up to 42-fold.ConclusionThe engineered E. coli strains and the two-step procedure presented here led to a remarkable increase in the solubility of a various recombinant proteins and should be applicable to a wide range of target proteins produced in biotechnology.

Trigger Factor and DnaK possess overlapping substrate pools and binding specificities

Ribosome‐associated Trigger Factor (TF) and the DnaK chaperone system assist the folding of newly synthesized proteins in Escherichia coli. Here, we show that DnaK and TF share a common substrate pool in vivo. In TF‐deficient cells, Δtig, depleted for DnaK and DnaJ the amount of aggregated proteins increases with increasing temperature, amounting to 10% of total soluble protein (approximately 340 protein species) at 37°C. A similar population of proteins aggregated in DnaK depleted tig+ cells, albeit to a much lower extent. Ninety‐four aggregated proteins isolated from DnaK‐ and DnaJ‐depleted Δtig cells were identified by mass spectrometry and found to include essential cytosolic proteins.

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 TFs 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.

A dual function for chaperones SSB–RAC and the NAC nascent polypeptide–associated complex on ribosomes

In addition to assisting with protein folding, SSB and NAC also regulate ribosome biogenesis (see also companion paper from Albanèse et al. in this issue).

Molecular mechanism and structure of Trigger Factor bound to the translating ribosome

Ribosome‐associated chaperone Trigger Factor (TF) initiates folding of newly synthesized proteins in bacteria. Here, we pinpoint by site‐specific crosslinking the sequence of molecular interactions of Escherichia coli TF and nascent chains during translation. Furthermore, we provide the first full‐length structure of TF associated with ribosome–nascent chain complexes by using cryo‐electron microscopy. In its active state, TF arches over the ribosomal exit tunnel accepting nascent chains in a protective void. The growing nascent chain initially follows a predefined path through the entire interior of TF in an unfolded conformation, and even after folding into a domain it remains accommodated inside the protective cavity of ribosome‐bound TF. The adaptability to accept nascent chains of different length and folding states may explain how TF is able to assist co‐translational folding of all kinds of nascent polypeptides during ongoing synthesis. Moreover, we suggest a model of how TFs chaperoning function can be coordinated with the co‐translational processing and membrane targeting of nascent polypeptides by other ribosome‐associated factors.