Cooperation of the prolyl isomerase and chaperone activities of the protein folding catalyst SlyD

The SlyD (sensitive to lysis D) protein of Escherichia coli is a folding enzyme with a chaperone domain and a prolyl isomerase domain of the FK506 binding protein type. Here we investigated how the two domains and their interplay are optimized for function in protein folding. Unfolded protein molecules initially form a highly dynamic complex with the chaperone domain of SlyD, and they are then transferred to the prolyl isomerase domain. The turnover number of the prolyl isomerase site is very high and guarantees that, after transfer, prolyl peptide bonds in substrate proteins are isomerized very rapidly. The Michaelis constant of catalyzed folding reflects the substrate affinity of the chaperone domain, and the turnover number is presumably determined by the rate of productive substrate transfer from the chaperone to the prolyl isomerase site and by the intrinsic propensity of the refolding protein chain to leave the active site with the native prolyl isomer. The efficiency of substrate transfer is high because dissociation from the chaperone site is very fast and because the two sites are close to each other. Protein molecules that left the prolyl isomerase site with an incorrect prolyl isomer can rapidly be re-bound by the chaperone domain because the association rate is very high as well.     

Folding and domain-domain interactions of the chaperone PapD measured by 19F NMR

The folding of the two-domain bacterial chaperone PapD has been studied to develop an understanding of the relationship between individual domain folding and the formation of domain-domain interactions. PapD contains six phenylalanine residues, four in the N-terminal domain and two in the C-terminal domain. To examine the folding properties of PapD, the protein was both uniformly and site-specifically labeled with p-fluoro-phenylalanine ((19)F-Phe) for (19)F NMR studies, in conjunction with those of circular dichroism and fluorescence. In equilibrium denaturation experiments monitored by (19)F NMR, the loss of (19)F-Phe native intensity for both the N- and C-terminal domains shows the same dependence on urea concentration. For the N-terminal domain the loss of native intensity is mirrored by the appearance of separate denatured resonances. For the C-terminal domain, which contains residues Phe 168 and Phe 205, intermediate as well as denatured resonances appear. These intermediate resonances persist at denaturant concentrations well beyond the loss of native resonance intensity and appear in kinetic refolding (19)F NMR experiments. In double-jump (19)F NMR experiments in which proline isomerization does not affect the refolding kinetics, the formation of domain-domain interactions is fast if the protein is denatured for only a short time. However, with increasing time of denaturation the native intensities of the N- and C-terminal domains decrease, and the denatured resonances of the N-terminal domain and the intermediate resonances of the C-terminal domain accumulate. The rate of loss of the N-terminal domain resonances is consistent with a cis to trans isomerization process, indicating that from an equilibrium denatured state the slow refolding of PapD is due to the trans to cis isomerization of one or both of the N-terminal cis proline residues. The data indicate that both the N- and C-terminal domains must fold into a native conformation prior to the formation of domain-domain interactions.     

Functional characterization of two novel parvulins in Trypanosoma brucei

Parvulins belong to a family of peptidyl-prolyl cis/trans isomerases (PPIases) that catalyze the cis/trans conformations of prolyl-peptidyl bonds. Herein, we characterized two novel parvulins, TbPIN1 and TbPAR42, in Trypanosoma brucei. TbPIN1, a 115 amino-acid protein, contains a single PPIase domain but lacks the N-terminal WW domain. Using NMR spectroscopy, TbPIN1 was found to exhibit PPIase activity toward a phosphorylated substrate. Overexpression of TbPIN1 can rescue the impaired temperature-sensitive phenotype in a mutant yeast strain. TbPAR42, containing 383 amino acids, comprises a novel FHA domain at its N terminus and a C-terminal PPIase domain but is a non-Pin1-type PPIase. Functionally, a knockdown of TbPAR42 in its procyclic form results in reduced proliferation rates suggesting an important role in cell growth.     

Crystal Structure Determination and Functional Characterization of the Metallochaperone SlyD from Thermus thermophilus

SlyD (sensitive to lysis D; product of the slyD gene) is a prolyl isomerase [peptidyl-prolyl cis/trans isomerase (PPIase)] of the FK506 binding protein (FKBP) type with chaperone properties. X-ray structures derived from three different crystal forms reveal that SlyD from Thermus thermophilus consists of two domains representing two functional units. PPIase activity is located in a typical FKBP domain, whereas chaperone function is associated with the autonomously folded insert-in-flap (IF) domain. The two isolated domains are stable and functional in solution, but the presence of the IF domain increases the PPIase catalytic efficiency of the FKBP domain by 2 orders of magnitude, suggesting that the two domains act synergistically to assist the folding of polypeptide chains. The substrate binding surface of SlyD from T. thermophilus was mapped by NMR chemical shift perturbations to hydrophobic residues of the IF domain, which exhibits significantly reduced thermodynamic stability according to NMR hydrogen/deuterium exchange and fluorescence equilibrium transition experiments. Based on structural homologies, we hypothesize that this is due to the absence of a stabilizing β-strand, suggesting in turn a mechanism for chaperone activity by ‘donor-strand complementation.’ Furthermore, we identified a conserved metal (Ni²⁺) binding site at the C-terminal SlyD-specific helical appendix of the FKBP domain, which may play a role in metalloprotein assembly.     

Structural and functional studies of FkpA from Escherichia coli, a cis/trans peptidyl-prolyl isomerase with chaperone activity

The protein FkpA from the periplasm of Escherichia coli exhibits both cis/trans peptidyl-prolyl isomerase (PPIase) and chaperone activities. The crystal structure of the protein has been determined in three different forms: as the full-length native molecule, as a truncated form lacking the last 21 residues, and as the same truncated form in complex with the immunosuppressant ligand, FK506. FkpA is a dimeric molecule in which the 245-residue subunit is divided into two domains. The N-terminal domain includes three helices that are interlaced with those of the other subunit to provide all inter-subunit contacts maintaining the dimeric species. The C-terminal domain, which belongs to the FK506-binding protein (FKBP) family, binds the FK506 ligand. The overall form of the dimer is V-shaped, and the different crystal structures reveal a flexibility in the relative orientation of the two C-terminal domains located at the extremities of the V. The deletion mutant FkpNL, comprising the N-terminal domain only, exists in solution as a mixture of monomeric and dimeric species, and exhibits chaperone activity. By contrast, a deletion mutant comprising the C-terminal domain only is monomeric, and although it shows PPIase activity, it is devoid of chaperone function. These results suggest that the chaperone and catalytic activities reside in the N and C-terminal domains, respectively. Accordingly, the observed mobility of the C-terminal domains of the dimeric molecule could effectively adapt these two independent folding functions of FkpA to polypeptide substrates.     

Generation of a Highly Active Folding Enzyme by Combining a Parvulin-Type Prolyl Isomerase from SurA with an Unrelated Chaperone Domain

Parvulins are small prolyl isomerases and serve as catalytic domains of folding enzymes. SurA (survival protein A) from the periplasm of Escherichia coli consists of an inactive (Par1) and an active (Par2) parvulin domain as well as a chaperone domain. In the absence of the chaperone domain, the folding activity of Par2 is virtually abolished. We created a chimeric protein by inserting the chaperone domain of SlyD, an unrelated folding enzyme from the FKBP family, into a loop of the isolated Par2 domain of SurA. This increased its folding activity 450-fold to a value higher than the activity of SurA, in which Par2 is linked with its natural chaperone domain. In the presence of both the natural and the foreign chaperone domain, the folding activity of Par2 was 1500-fold increased. Related and unrelated chaperone domains thus are similarly efficient in enhancing the folding activity of the prolyl isomerase Par2. A sequence analysis of various chaperone domains suggests that clusters of exposed methionine residues in mobile chain regions might be important for a generic interaction with unfolded protein chains. This binding is highly dynamic to allow frequent transfer of folding protein chains between chaperone and catalytic domains.     

Nickel binding and [NiFe]-hydrogenase maturation by the metallochaperone SlyD with a single metal-binding site in Escherichia coli

SlyD (sensitive to lysis D) is a nickel metallochaperone involved in the maturation of [NiFe]-hydrogenases in Escherichia coli (E. coli) and specifically contributes to the nickel delivery step during enzyme biosynthesis. This protein contains a C-terminal metal-binding domain that is rich in potential metal-binding residues that enable SlyD to bind multiple nickel ions with high affinity. The SlyD homolog from Thermus thermophilus does not contain the extended cysteine- and histidine-rich C-terminal tail of the E. coli protein, yet it binds a single Ni(II) ion tightly. To investigate whether a single metal-binding motif can functionally replace the full-length domain, we generated a truncation of E. coli SlyD, SlyD155. Ni(II) binding to SlyD155 was investigated by using isothermal titration calorimetry, NMR and electrospray ionization mass spectrometry measurements. This in vitro characterization revealed that SlyD155 contains a single metal-binding motif with high affinity for nickel. Structural characterization by X-ray absorption spectroscopy and NMR indicated that nickel was coordinated in an octahedral geometry with at least two histidines as ligands. Heterodimerization between SlyD and another hydrogenase accessory protein, HypB, is essential for optimal hydrogenase maturation and was confirmed for SlyD155 via cross-linking experiments and NMR titrations, as were conserved chaperone and peptidyl-prolyl isomerase activities. Although these properties of SlyD are preserved in the truncated version, it does not modulate nickel binding to HypB in vitro or contribute to the maturation of [NiFe]-hydrogenases in vivo, unlike the full-length protein. This study highlights the importance of the unusual metal-binding domain of E. coli SlyD in hydrogenase biogenesis.     

Characteristic domain motion in the ribosome recycling factor revealed by 15N NMR relaxation experiments and molecular dynamics simulations

The backbone dynamics of ribosome recycling factor (RRF) from Escherichia coli in water were characterized by (15)N NMR relaxation analysis and molecular dynamics (MD) simulation. RRF is composed of two domains connected by a joint region that consists of two peptide chains, such that the overall structure seems to mimic that of tRNA. MD trajectories indicated that the relative orientation of domains varies on the nanosecond time scale. We analyzed the observed (15)N T(1), T(2), and NOE using an extended model-free spectral density function in which the domain motions with a nanosecond time scale were considered. At 30 degrees C, the order parameters of slow motion () were determined to be approximately 0.9 for domain I and 0.7 for domain II, respectively. These values indicate that domain I is nearly fixed on the molecular diffusion frame, and domain II is wobbling in a cone for which the semi-angle is about 30 degrees.     

Combination of the human prolyl isomerase FKBP12 with unrelated chaperone domains leads to chimeric folding enzymes with high activity

Folding enzymes often use distinct domains for the binding of substrate proteins ("chaperone domains") and for the catalysis of slow folding reactions such as disulfide formation or prolyl isomerization. The human prolyl isomerase FKBP12 is a small single-domain protein without a chaperone domain. Its very low folding activity could previously be increased by inserting the chaperone domain from the homolog SlyD (sensitive-to-lysis protein D) of Escherichia coli. We now inserted three unrelated chaperone domains into human FKBP12: the apical domain of the chaperonin GroEL from E. coli, the chaperone domain of protein disulfide isomerase from yeast, or the chaperone domain of SurA from the periplasm of E. coli. All three conveyed FKBP12 with a high affinity for unfolded proteins and increased its folding activity. Substrate binding and release of the chimeric folding enzymes were found to be very fast. This allows rapid substrate transfer from the chaperone domain to the catalytic domain and ensures efficient rebinding of protein chains that were unable to complete folding. The advantage of having separate sites, first for generic protein binding and then for specific catalysis, explains why our construction of the artificial folding enzymes with foreign chaperone domains was successful.     

SlyD proteins from different species exhibit high prolyl isomerase and chaperone activities

SlyD is a putative folding helper protein from the Escherichia coli cytosol, which consists of an N-terminal prolyl isomerase domain of the FKBP type and a presumably unstructured C-terminal tail. We produced truncated versions without this tail (SlyD) for SlyD from E. coli, as well as for the SlyD orthologues from Yersinia pestis, Treponema pallidum, Pasteurella multocida, and Vibrio cholerae. They are monomeric in solution and unfold reversibly. All SlyD variants catalyze the proline-limited refolding of ribonuclease T1 with very high efficiencies, and the specificity constants (kcat/KM) are equal to approximately 10(6) M(-1) s(-1). These large values originate from the high affinities of the SlyD orthologues for unfolded RCM-T1, which are reflected in low KM values of approximately 1 microM. SlyD also exhibits pronounced chaperone properties. Permanently unfolded proteins bind with high affinity to SlyD and thus inhibit its prolyl isomerase activity. The unfolded protein chains do not need to contain proline residues to be recognized and bound by SlyD. The conservation of prolyl isomerase activity and chaperone properties within the SlyD family suggests that these proteins might act as true folding helpers in the bacterial cytosol. The SlyD proteins are also well suited for biotechnological applications. As fusion partners they facilitate the refolding and increase the solubility of aggregation-prone proteins such as the gp41 ectodomain fragment of HIV-1.     

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.     

Multifaceted SlyD from <Emphasis Type="Italic">Helicobacter pylori</Emphasis>: implication in [NiFe] hydrogenase maturation

SlyD belongs to the FK506-binding protein (FKBP) family with both peptidylprolyl isomerase (PPIase) and chaperone activities, and is considered to be a ubiquitous cytosolic protein-folding facilitator in bacteria. It possesses a histidine- and cysteine-rich C-terminus binding to selected divalent metal ions (e.g., Ni²⁺, Zn²⁺), which is important for its involvement in the maturation processes of metalloenzymes. We have determined the solution structure of C-terminus-truncated SlyD from Helicobacter pylori (HpSlyDΔC). HpSlyDΔC folds into two well-separated, orientation-independent domains: the PPIase-active FKBP domain and the chaperone-active insert-in-flap (IF) domain. The FKBP domain consists of a four-stranded antiparallel β-sheet with an α-helix on one side, whereas the IF domain folds into a four-stranded antiparallel β-sheet accompanied by a short α-helix. Intact H. pylori SlyD binds both Ni²⁺ and Zn²⁺, with dissociation constants of 2.74 and 3.79 μM respectively. Intriguingly, binding of Ni²⁺ instead of Zn²⁺ induces protein conformational changes around the active sites of the FKBP domain, implicating a regulatory role of nickel. The twin-arginine translocation (Tat) signal peptide from the small subunit of [NiFe] hydrogenase (HydA) binds the protein at the IF domain. Nickel binding and the recognition of the Tat signal peptide by the protein suggest that SlyD participates in [NiFe] hydrogenase maturation processes.     

Peptide binding induces large scale changes in inter-domain mobility in human Pin1

Pin1 is a peptidyl-prolyl cis/trans isomerase (PPIase) essential for cell cycle regulation. Pin1-catalyzed peptidyl-prolyl isomerization provides a key conformational switch to activate phosphorylation sites with the common phospho-Ser/Thr-Pro sequence motif. This motif is ubiquitously exploited in cellular response to a variety of signals. Pin1 is able to bind phospho-Ser/Thr-Pro-containing sequences at two different sites that compete for the same substrate. One binding site is located within the N-terminal WW domain, which is essential for protein targeting and localization. The other binding site is located in the C-terminal catalytic domain, which is structural homologous to the FK506-binding protein (FKBP) class of PPIases. A flexible linker of 12 residues connects the WW and catalytic domain. To characterize the structure and dynamics of full-length Pin1 in solution, high resolution NMR methods have been used to map the nature of interactions between the two domains of Pin1. In addition, the influence of target peptides on domain interactions has been investigated. The studies reveal a dynamic picture of the domain interactions. 15N spin relaxation data, differential chemical shift mapping, and residual dipolar coupling data indicate that Pin1 can either behave as two independent domains connected by the flexible linker or as a single intact domain with some amount of hinge bending motion depending on the sequence of the bound peptide. The functional importance of the modulation of relative domain flexibility in light of the multitude of interaction partners of Pin1 is discussed.     

The role of complex formation between the Escherichia coli hydrogenase accessory factors HypB and SlyD

The Escherichia coli protein SlyD is a member of the FK-506-binding protein family of peptidylprolyl isomerases. In addition to its peptidylprolyl isomerase domain, SlyD is composed of a molecular chaperone domain and a C-terminal tail rich in potential metal-binding residues. SlyD interacts with the [NiFe]-hydrogenase accessory protein HypB and contributes to nickel insertion during biosynthesis of the hydrogenase metallocenter. This study examines the HypB-SlyD complex and its significance in hydrogenase activation. Protein variants were prepared to delineate the interface between HypB and SlyD. Complex formation requires the HypB linker region located between the high affinity N-terminal Ni(II) site and the GTPase domain of the protein. In the case of SlyD, the deletion of a short loop in the chaperone domain abrogates the interaction with HypB. Mutations in either protein that disrupt complex formation in vitro also result in deficient hydrogenase production in vivo, indicating that the contact between HypB and SlyD is important for hydrogenase maturation. Surprisingly, SlyD stimulates release of nickel from the high affinity Ni(II)-binding site of HypB, an activity that is also disrupted by mutations that affect complex formation. Furthermore, a SlyD truncation lacking the C-terminal metal-binding tail still interacts with HypB but is deficient in stimulating metal release and is not functional in vivo. These results suggest that SlyD could activate metal release from HypB during metallation of the [NiFe] hydrogenase.     

Light-controlled protein dynamics observed with neutron spin echo measurements

A photoresponsive surfactant has been used as a means to control protein structure and dynamics with light illumination. This cationic azobenzene surfactant, azoTAB, which undergoes a reversible photoisomerization upon exposure to the appropriate wavelength of light, adopts a relatively hydrophobic, trans structure under visible light illumination and a relatively hydrophilic cis structure under UV light illumination. Small-angle neutron scattering (SANS) and neutron spin echo (NSE) spectroscopy were used to measure the tertiary structure and internal dynamics of lysozyme in the presence of the photosurfactant, respectively. The SANS-based in vitro structures indicate that under visible light the photosurfactant induces partial unfolding that principally occurs away from the active site near the hinge region connecting the α and β domains. Upon UV exposure, however, the protein refolds to a nativelike structure. At the same time, enhanced internal dynamics of lysozyme were detected with the surfactant in the trans form through NSE measurements of the Q-dependent effective diffusion coefficient (D(eff)) of the protein. In contrast, the D(eff) values of lysozyme in the presence of cis azoTAB largely agree with the rigid-body calculation as well as those measured for pure lysozyme, suggesting that the native protein is dormant on the nanosecond time and nanometer length scales. Lysozyme internal motions were modeled by assuming a protein of two (α and β domains) or three (α and β domains and the hinge region) domains connects by either soft linkers or rigid, freely rotating bonds. Protein dynamics were also tracked with Fourier transform infrared spectroscopy through hydrogen-deuterium exchange kinetics, which further demonstrated enhanced protein flexibility induced by the trans form of the surfactant relative to the native protein. Ensemble-averaged intramolecular fluorescent resonance energy transfer measurements similarly demonstrated the enhanced dynamics of lysozyme with the trans form of the photosurfactant. Previous results have shown a significant increase in protein activity in the presence of azoTAB in the trans conformation. Combined, these results provide insight into a unique light-based method of controlling protein structure, dynamics, and function and strongly support the relevance of large domain motions for the activity of proteins.     

Insertion of a chaperone domain converts FKBP12 into a powerful catalyst of protein folding

The catalytic activity of human FKBP12 as a prolyl isomerase is high towards short peptides, but very low in proline-limited protein folding reactions. In contrast, the SlyD proteins, which are members of the FKBP family, are highly active as folding enzymes. They contain an extra "insert-in-flap" or IF domain near the prolyl isomerase active site. The excision of this domain did not affect the prolyl isomerase activity of SlyD from Escherichia coli towards short peptide substrates but abolished its catalytic activity in proline-limited protein folding reactions. The reciprocal insertion of the IF domain of SlyD into human FKBP12 increased its folding activity 200-fold and generated a folding catalyst that is more active than SlyD itself. The IF domain binds to refolding protein chains and thus functions as a chaperone module. A prolyl isomerase catalytic site and a separate chaperone site with an adapted affinity for refolding protein chains are the key elements for a productive coupling between the catalysis of prolyl isomerization and conformational folding in the enzymatic mechanisms of SlyD and other prolyl isomerases, such as trigger factor and FkpA.     

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 SlyDΔIF, 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.     

Direct evidence by H/D exchange and ESI-MS for transient unproductive domain interaction in the refolding of an antibody scFv fragment

The refolding kinetics of a single-chain Fv (scFv) fragment, derived from a stabilized mutant of the phosphorylcholine binding antibody McPC603, was investigated by H/D exchange and ESI-MS and compared with the folding kinetics of its constituting domains V(H) and V(L). Both V(H) and V(L) adopt essentially native-like exchange protection within the dead time of the manual-mixing H/D exchange experiment (10 s) and in the case of V(L), which contains two cis-prolines in the native conformation, this fast protection is independent of proline cis/trans isomerization. At the earliest time point resolvable by manual mixing, fewer deuterons are protected in the scFv fragment than in the two isolated domains together, despite the fact that the scFv fragment is significantly more stable than V(L) and V(H). Full H/D exchange protection in the scFv fragment is gained on a time scale of minutes. This means that the domains in the scFv fragment do not refold independently. Rather, they associate prematurely and in nonnative form, a kinetic trap. Unproductive domain association is observed both after equilibrium- and short-term denaturation. For the equilibrium-denatured scFv fragment, whose native structure formation is dependent on a cis conformation of an interface proline in V(L), this cis/trans isomerization reaction proceeds about one order in magnitude more slowly than the escape from the trap to a conformation where full H/D exchange protection is already achieved. We interpret these data in terms of a general kinetic scheme involving intermediates with and without domain association.     

Prolyl isomerases in a minimal cell. Catalysis of protein folding by trigger factor from Mycoplasma genitalium.

Peptidyl-prolyl cis/trans isomerases (PPIases) catalyze the isomerization of prolyl peptide bonds. Distinct families of this class of enzymes are involved in protein folding in vitro, whereas their significance in free living organisms is not known. Previously, we inspected the smallest known genome of a self-replicating organism and found that Mycoplasma genitalium is devoid of all known PPIases except the trigger factor. Despite the extensive sequence information becoming available, most genes remain hypothetical and enzyme activities in many species have not been assigned to an open reading frame. Therefore, we studied the PPIase activity in crude extracts of M. genitalium. We showed that this is solely attributed to a single enzyme activity, the trigger factor. Characterization of this enzyme revealed that its PPIase activity resides in a central 12-kDa domain. Only the complete trigger factor is able to cis/trans isomerize extended peptide substrates, while the PPIase domain alone can not. The N- and the C-terminal domains of the trigger factor seem to function in binding of proteins as substrates, as demonstrated by protein refolding experiments, in which the complete trigger factor catalyzed protein refolding towards a model protein 500-fold more efficiently than the isolated central PPIase domain. Protein modeling studies suggest that the PPIase domain can fold in a similar way as the PPIase domain of FK506 binding proteins (FKBPs), one class of PPIases, despite only very limited sequence homology. Differences at the active site explain why this enzyme is not inhibited by FK506 in contrast with FKBPs. Trigger factor expressed in Escherichia coli confirms its additional chaperone functions, as shown by its association with chaperones GroEL and GroES after induction of misfolding. In contrast, the isolated PPIase-domain lacks any association with chaperones from E. coli. In summary, trigger factor of M. genitalium is the single folding isomerase of this organism, which harbors an enzymatically active PPIase domain with structural homology to FKBPs. Its additional domains confer its ability to be an efficient catalyst of protein folding. The protein folding machinery is conserved and shows a dual function as a chaperone and a prolyl isomerase.     

Single proline residues can dictate the oxidative folding pathways of cysteine-rich peptides

The cysteine-rich N and C-terminal domains of minicollagen-1 from Hydra nematocysts fold with excesses of oxidized/reduced glutathione (10:1) into globular structures with distinct cystine frameworks despite their identical cysteine sequence pattern. An additional main difference is the cis conformation of a conserved proline residue in the N-terminal and the trans conformation of this residue in the C-terminal domain. Comparative analysis of the oxidative folding revealed for the C-terminal domain a fast and highly cooperative formation of a single disulfide isomer. Conversely, oxidation of the N-terminal domain proceeds mainly via an intermediate that results from the fast quasi-stochastic disulfide formation according to the proximity rule. The rate of conversion of the bead-like isomer into the globular end-product is largely dominated by the trans-to-cis isomerization of the critical proline residue as well assessed by its replacement with (4R)- and (4S)-fluoroproline known to exhibit distinct propensities for the trans and cis conformation, respectively. Independently, whether the trans or cis conformation is favored by these substitutions, both analogues retain sufficient sequence-encoded information to fold almost quantitatively into the identical cystine framework and thus spatial structure of the parent peptide with the critical proline residue as cis isomer, but at rates significantly lower for the (4R) than for the (4S)-fluoroproline analogue. Correspondingly, other sequence-encoded structural elements have to act as a driving force for these unidirectional folding pathways despite the rather simple sequence composition consisting only of aliphatic residues, some proline and only one aromatic residue (tyrosine) in the core parts of the C and N-terminal domains. The two cysteine-rich domains of minicollagen-1 may well represent ideal targets for ab initio structure calculations in order to learn more about the elementary information encoded in such primordial molecules.