Insertion of a Chaperone Domain Converts FKBP12 into a Powerful Catalyst of Protein Folding

A library of fluorescent peptides for exploring the substrate specificities of prolyl isomerases

To fully explore the substrate specificities of prolyl isomerases, we synthesized a library of 20 tetrapeptides that are labeled with a 2-aminobenzoyl (Abz) group at the amino terminus and a p-nitroanilide (pNA) group at the carboxy terminus. In this peptide library of the general formula Abz-Ala-Xaa-Pro-Phe-pNA, the position Xaa before the proline is occupied by all 20 proteinogenic amino acids. A conformational analysis of the peptide by molecular dynamics simulations and by NMR spectroscopy showed that the mutual distance between the Abz and pNA moieties in the peptides depends on the isomeric state of the Xaa-Pro bond. In the cis, but not in the trans form, there are significant chemical shift changes of the Abz and pNA moieties, because their aromatic rings are close to each other. This proximity also leads to a strong quenching of Abz fluorescence, which, in combination with a solvent jump, was used to devise a sensitive assay for prolyl isomerases. Unlike the traditional assay, it is not coupled with peptide proteolysis and thus can be employed for protease-sensitive prolyl isomerases as well. The peptide library was used to provide a complete set of P1-site specificities for prototypic human members of the three prolyl isomerase families, FKBP12, cyclophilin 18, and parvulin 14. In a second application, the substrate specificity of SlyD, a protease-sensitive prolyl isomerase from Escherichia coli, was characterized and compared with that of human FKBP12 as well as with homologues from other bacteria.

Chaperone domains convert prolyl isomerases into generic catalysts of protein folding

The cis/trans isomerization of peptide bonds before proline (prolyl bonds) is a rate-limiting step in many protein folding reactions, and it is used to switch between alternate functional states of folded proteins. Several prolyl isomerases of the FK506-binding protein family, such as trigger factor, SlyD, and FkpA, contain chaperone domains and are assumed to assist protein folding in vivo. The prolyl isomerase activity of FK506-binding proteins strongly depends on the nature of residue Xaa of the Xaa-Pro bond. We confirmed this in assays with a library of tetrapeptides in which position Xaa was occupied by all 20 aa. A high sequence specificity seems inconsistent with a generic function of prolyl isomerases in protein folding. Accordingly, we constructed a library of protein variants with all 20 aa at position Xaa before a rate-limiting cis proline and used it to investigate the performance of trigger factor and SlyD as catalysts of proline-limited folding. The efficiencies of both prolyl isomerases were higher than in the tetrapeptide assays, and, intriguingly, this high activity was almost independent of the nature of the residue before the proline. Apparently, the almost indiscriminate binding of the chaperone domain to the refolding protein chain overrides the inherently high sequence specificity of the prolyl isomerase site. The catalytic performance of these folding enzymes is thus determined by generic substrate recognition at the chaperone domain and efficient transfer to the active site in the prolyl isomerase domain.

The interaction of the Escherichia coli protein SlyD with nickel ions illuminates the mechanism of regulation of its peptidyl-prolyl isomerase activity

The sensitive to lysis D (SlyD) protein from Escherichia coli is related to the FK506-binding protein family, and it harbours both peptidyl-prolyl cis-trans isomerase (PPIase) and chaperone-like activity, preventing aggregation and promoting the correct folding of other proteins. Whereas a functional role of SlyD as a protein-folding catalyst in vivo remains unclear, SlyD has been shown to be an essential component for [Ni-Fe]-hydrogenase metallocentre assembly in bacteria. Interestingly, the isomerase activity of SlyD is uniquely modulated by nickel ions, which possibly regulate its functions in response to external stimuli. In this work, we investigated the solution structure of SlyD and its interaction with nickel ions, enabling us to gain insights into the molecular mechanism of this regulation. We have revealed that the PPIase module of SlyD contains an additional C-terminal alpha-helix packed against the catalytic site of the domain; unexpectedly, our results show that the interaction of SlyD with nickel ions entails participation of the novel structural features of the PPIase domain, eliciting structural alterations of the catalytic pocket. We suggest that such conformational rearrangements upon metal binding underlie the ability of nickel ions to regulate the isomerase activity of SlyD.

Engineering of monomeric FK506-binding protein 22 with peptidyl prolyl cis-trans isomerase. Importance of a V-shaped dimeric structure for binding to protein substrate

FK506-binding protein 22 (FKBP22) from the psychrotrophic bacterium Shewanella sp. SIB1 is a homodimeric protein with peptidyl prolyl cis-trans isomerase (PPIase) (EC 5.2.1.8) activity. Each monomer consists of 205 amino acid residues. According to a tertiary model, SIB1 FKBP22 assumes a V-shaped structure, in which two monomers interact with each other at their N-termini. Each monomer consists of an N-terminal domain with a dimerization core and a C-terminal catalytic domain, which are separated by a 40-residue-long a-helix. To clarify the role of this V-shaped structure, we constructed a mutant protein, in which the N-domain is tandemly repeated through a flexible linker. This protein, termed NNC-FKBP22, is designed such that two repetitive N-domains are folded into a structure similar to that of the Shewanella sp. SIB1 FKBP22 wild-type protein (WT). NNC-FKBP22 was overproduced in Escherichia coli in a His-tagged form, purified and biochemically characterized. Gel-filtration chromatography and ultracentrifugation analyses indicate that NNC-FKBP22 exists as a monomer. Analysis of thermal denaturation using differential scanning calorimetry indicates that NNC-FKBP22 unfolds with two transitions, as does the WT protein. NNC-FKBP22 exhibited PPIase activity for both peptide and protein substrates. However, in contrast to its activity for peptide substrate, which was comparable to that of the WT protein, its activity for protein substrate was reduced by five- to six-fold, compared to that of the WT. Surface plasmon resonance analyses indicate that NNC-FKBP22 binds to a reduced form of a-lactalbumin with a six-fold weaker affinity than that of WT. These results suggest that a V-shaped structure of SIB1 FKBP22 is important for efficient binding to a protein substrate.

Biochemical characterization of the prolyl 3-hydroxylase 1.cartilage-associated protein.cyclophilin B complex

The rough endoplasmic reticulum-resident protein complex consisting of prolyl 3-hydroxylase 1 (P3H1), cartilage-associated protein (CRTAP), and cyclophilin B (CypB) can be isolated from chick embryos on a gelatin-Sepharose column, indicating some involvement in the biosynthesis of procollagens. Prolyl 3-hydroxylase 1 modifies a single proline residue in the alpha chains of type I, II, and III collagens to (3S)-hydroxyproline. The peptidyl-prolyl cis-trans isomerase activity of cyclophilin B was shown previously to catalyze the rate of triple helix formation. Here we show that cyclophilin B in the complex shows peptidyl-prolyl cis-trans isomerase activity and that the P3H1.CRTAP.CypB complex has another important function: it acts as a chaperone molecule when tested with two classical chaperone assays. The P3H1.CRTAP.CypB complex inhibited the thermal aggregation of citrate synthase and was active in the denatured rhodanese refolding and aggregation assay. The chaperone activity of the complex was higher than that of protein-disulfide isomerase, a well characterized chaperone. The P3H1.CRTAP.CypB complex also delayed the in vitro fibril formation of type I collagen, indicating that this complex is also able to interact with triple helical collagen and acts as a collagen chaperone.

NMR solution structure of SlyD from Escherichia coli: spatial separation of prolyl isomerase and chaperone function

SlyD (sensitive to lysis D) is a putative folding helper from the bacterial cytosol and harbors prolyl isomerase and chaperone activities. We determined the solution NMR structure of a truncated version of SlyD (1-165) from Escherichia coli (SlyD*) that lacks the presumably unstructured C-terminal tail. SlyD* consists of two well-separated domains: the FKBP domain, which harbors the prolyl isomerase activity, and the insert-in-flap (IF) domain, which harbors the chaperone activity. The IF domain is inserted into a loop of the FKBP domain near the prolyl isomerase active site. The NMR structure of SlyD* showed no distinct orientation of the two domains relative to each other. In the FKBP domain, Tyr68 points into the active site, which might explain the lowered intrinsic prolyl isomerase activity and the much lower FK506 binding affinity of the protein compared with archetype human FKBP12 (human FK506 binding protein with 12 kDa). The thermodynamics and kinetics of substrate binding by SlyD* were quantified by fluorescence resonance energy transfer. NMR titration experiments revealed that the IF domain recognizes and binds unfolded or partially folded proteins and peptides. Insulin aggregation is markedly slowed by SlyD* as evidenced by two-dimensional NMR spectroscopy in real time, probably due to SlyD* binding to denatured insulin. The capacity of the IF domain to establish an initial encounter-collision complex, together with the flexible orientation of the two interacting domains, makes SlyD* a very powerful catalyst of protein folding.

Consequences of domain insertion on the stability and folding mechanism of a protein

SlyD, the sensitive-to-lysis protein from Escherichia coli, consists of two domains. They are not arranged successively along the protein chain, but one domain, the "insert-in-flap" (IF) domain, is inserted internally as a guest into a surface loop of the host domain, which is a prolyl isomerase of the FK506 binding protein (FKBP) type. We used SlyD as a model to elucidate how such a domain insertion affects the stability and folding mechanism of the host and the guest domain. For these studies, the two-domain protein was compared with a single-domain variant SlyDDeltaIF, SlyD* without the chaperone domain (residues 1-69 and 130-165) in which the IF domain was removed and replaced by a short loop, as present in human FKBP12. Equilibrium unfolding and folding kinetics followed an apparent two-state mechanism in the absence and in the presence of the IF domain. The inserted domain decreased, however, the stability of the host domain in the transition region and decelerated its refolding reaction by about 10-fold. This originates from the interruption of the chain connectivity by the IF domain and its inherent instability. To monitor folding processes in this domain selectively, a Trp residue was introduced as fluorescent probe. Kinetic double-mixing experiments revealed that, in intact SlyD, the IF domain folds and unfolds about 1000-fold more rapidly than the FKBP domain, and that it is strongly stabilized when linked with the folded FKBP domain. The unfolding limbs of the kinetic chevrons of SlyD show a strong downward curvature. This deviation from linearity is not caused by a transition-state movement, as often assumed, but by the accumulation of a silent unfolding intermediate at high denaturant concentrations. In this kinetic intermediate, the FKBP domain is still folded, whereas the IF domain is already unfolded.