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.     

Domain I of ribosomal protein L1 is sufficient for specific RNA binding

Ribosomal protein L1 has a dual function as a ribosomal protein binding 23S rRNA and as a translational repressor binding its mRNA. L1 is a two-domain protein with N- and C-termini located in domain I. Earlier it was shown that L1 interacts with the same targets on both rRNA and mRNA mainly through domain I. We have suggested that domain I is necessary and sufficient for specific RNA-binding by L1. To test this hypothesis, a truncation mutant of L1 from Thermus thermophilus, representing domain I, was constructed by deletion of the central part of the L1 sequence, which corresponds to domain II. It was shown that the isolated domain I forms stable complexes with specific fragments of both rRNA and mRNA. The crystal structure of the isolated domain I was determined and compared with the structure of this domain within the intact protein L1. This comparison revealed a close similarity of both structures. Our results confirm our suggestion that in protein L1 its domain I alone is sufficient for specific RNA binding, whereas domain II stabilizes the L1-rRNA complex.     

Crystal structure of receiver domain of putative NarL family response regulator spr1814 from Streptococcus pneumoniae in the absence and presence of the phosphoryl analog beryllofluoride

Spr1814 of Streptococcus pneumoniae is a putative response regulator (RR) that has four-helix helix-turn-helix DNA-binding domain and belongs to the NarL family. The prototypical RR contains two domains, an N-terminal receiver domain linked to a variable effector domain. The receiver domain functions as a phosphorylation-activated switch and contains the typical doubly wound five-stranded α/β fold. Here, we report the crystal structure of the receiver domain of spr1814 (spr1814(R)) determined in the absence and presence of beryllofluoride as a phosphoryl analog. Based on the overall structure, spr1814(R) was shown to contain the typical fold similar with other structures of the receiver domain; however, an additional linker region connecting the receiver and DNA-binding domain was inserted into the dimer interface of spr1814(R), resulting in the formation of unique dimer interface. Upon phosphorylation, the conformational change of the linker region was observed and this suggests that domain rearrangement between the receiver domain and effector domain could occur in full-length spr1814.     

High level expression of a synthetic gene coding for IgG-binding domain B of Staphylococcal protein A

A gene coding for one of the IgG-binding domains of Staphylococcal protein A, designated domain B, was chemically synthesized. This gene was tandemly repeated to give dimeric and tetrameric domain B genes by the use of two restriction enzymes which gave blunt ends. The genes were highly expressed in Escherichia coli to afford a large amount of dimeric and tetrameric domain B proteins. The single domain B protein was efficiently produced as a fusion protein with a salmon growth hormone fragment. The fusion protein was converted to monomeric domain B by cyanogen bromide cleavage. The CD spectra of the monomeric, dimeric and tetrameric domain B proteins were essentially the same as that of native form protein A, showing that their secondary structures were very similar. The dimeric and tetrameric domain B proteins formed precipitates with IgG as protein A. This system permits the efficient production of mutated single and multiple IgG-binding domains which can be used to study structural changes and protein A-immunoglobulin interactions.     

Identification of myosin II as a binding protein to the PH domain of protein kinase B

Myosin II was identified as a binding protein to the pleckstrin homology (PH) domain of protein kinase B (PKB) in CHO cell extract by using the glutathione S-transferase-fusion protein as a probe. When myosin II purified from rabbit skeletal muscle was employed, myosin II was shown to bind almost exclusively to the PH domain of PKB among the PH domain fusion proteins examined. The purified myosin II bound to the PH domain of PKB with a Kd value of 1.1 x 10(-7) M. Studies with a series of truncated molecules indicated that the whole structure of the PH domain is required for the binding of myosin II, and the binding to the PH domain was inhibited by phosphatidylinositol 4,5-bisphosphate. These results suggest that myosin II is a specific binding protein to the PH domain of particular proteins including PKB.     

The critical role of the stem region as a functional domain responsible for the oligomerization and Golgi localization of N-acetylglucosaminyltransferase V. The involvement of a domain homophilic interaction

We demonstrated that a region in the stem of N-acetylglucosaminyltransferase V (GnT-V), a Golgi resident protein, is not required for enzyme activity but serves as functional domain, responsible for intracellular localization. Deletion of the domain led to complete retention of the kinetic properties but resulted in the cell surface localization of the enzyme as well as its efficient secretion into the medium. The lack of this domain concomitantly abolished the disulfide-mediated oligomerization of GnT-V, which appears to confer the Golgi retention. When the domain was inserted into the stem region of a cell surface-localized type II membrane protein, the resulting chimeric protein was substantially oligomerized and predominantly localized in the intracellular organelle. Furthermore, it was found that the presence of this domain is exclusively responsible for homo-oligomer formation. This homophilic interaction appears to involve a hydrophobic cluster of residues in the alpha-helix of the domain, as indicated by secondary structure predictions. These findings suggest that the domain specifically participates in the Golgi retention of GnT-V, probably via inducing homo-oligomer formation, and would also provide a possible mechanism for the oligomerization, which is critical for localization in the Golgi.     

Roles of the three L‐domains in β‐retrovirus budding

Retroviral Gag protein plays a critical role during the late stage of virus budding and possesses a so‐called L‐domain containing PT/SAP, PPxY, YxxL or FPIV motifs that are critical for efficient budding. Mason–Pfizer monkey virus (M‐PMV) contains PSAP, PPPY, and YADL sequences in Gag. This study was performed to investigate the roles of these three L‐domain‐like sequences in virus replication in three different cell lines, 293T, COS‐7 and HeLa cells. It was found that the PPxY motif plays an essential role in progeny virus production as a major L‐domain in all three cell lines. The PSAP sequence was shown to function as an additional L‐domain in HeLa cells and to promote efficient release of M‐PMV; however, this sequence was dispensable for M‐PMV production in 293T and COS‐7 cells, suggesting that the role of the PSAP motif as an L‐domain in M‐PMV budding is cell type‐dependent. Viruses possessing multiple L‐domains appear to change the L‐domain usage to replicate in various cells. On the other hand, the YADL motif was required for M‐PMV production as a transport signal of Gag to the plasma membrane, but not as an L‐domain.     

The CAP-Gly domain of CYLD associates with the proline-rich sequence in NEMO/IKKgamma

CYLD was originally identified as the human familial cylindromatosis tumor suppressor. Recently, it was reported that CYLD directly interacts with NEMO/IKKgamma and TRAF2 in the NF-kappaB signaling pathway. The two proteins bind to a region of CYLD that contains a Cys-box motif and the third cytoskeleton-associated protein-glycine conserved (CAP-Gly) domain. Here we report that the third CAP-Gly domain of CYLD specifically interacts with one of the two proline-rich sequences of NEMO/IKKgamma. The tertiary structure of the CAP-Gly domain shares the five-stranded beta sheet topology with the SH3 domain, which is well known as a proline-rich sequence-recognition domain. However, chemical shift mapping revealed that the peptide binding site of the CAP-Gly domain is formed without the long peptide binding loop characteristic of the SH3 domain. Therefore, CAP-Gly is likely to be a novel proline-rich sequence binding domain with a mechanism different from that of the SH3 domain.     

Arginine residues in domain V have a central role for bacteria-binding activity of macrophage scavenger receptor MARCO

MARCO is a bacteria-binding macrophage-specific scavenger receptor that plays a role in innate immune response. MARCO has short intracellular and transmembrane domains, as well as a large extracellular domain composed of a spacer domain, a long collagenous domain, and a C-terminal scavenger receptor cysteine-rich domain (SRCR), domain V. As yet, no specific function has been assigned to the SRCR domain of scavenger receptors. In the present study, we generated several human and mouse MARCO variants with deletions or single amino acid substitutions and localized the primary bacteria-binding region to domain V. Furthermore, analysis of the MARCO variants containing only portions of domain V demonstrated a crucial role for an arginine-rich segment for this function. More precisely, the motif RXR was identified as an essential element for high-affinity bacterial binding. The results indicate that the binding properties of MARCO differ from those of the other class A scavenger receptors, SR-A and SRCL, whose ligand-binding function has been localized to the collagenous domain.     

Rich, a rho GTPase-activating protein domain-containing protein involved in signaling by Cdc42 and Rac1.

A previously unidentified Rho GTPase-activating protein (GAP) domain-containing protein was found in a yeast two-hybrid screen for cDNAs encoding proteins binding to the Src homology 3 domain of Cdc42-interacting protein 4 (CIP4). The protein was named RICH-1 (RhoGAP interacting with CIP4 homologues), and, in addition to the RhoGAP domain, it contained an N-terminal domain with endophilin homology and a C-terminal proline-rich domain. Transient transfections of RICH-1 indicated that it bound to CIP4 in vivo, as shown by co-immunoprecipitation experiments, as well as co-localization assays. In vitro assays demonstrated that the RhoGAP domain of RICH-1 catalyzed GTP hydrolysis on Cdc42 and Rac1, but not on RhoA. Ectopic expression of the RhoGAP domain as well as the full-length protein interfered with platelet-derived growth factor BB-induced membrane ruffling, but not with serum-induced stress fiber formation, further emphasizing the notion that, in vivo, RICH-1 is a GAP for Cdc42 and Rac1.     

Molecular dynamics study of time-correlated protein domain motions and molecular flexibility: cytochrome P450BM-3.

Time-correlated atomic motions were used to characterize protein domain boundaries from atomic coordinates generated by molecular dynamics simulations. A novel application of the dynamical cross-correlation matrix (DCCM) analysis tool was used to help identify putative protein domains. In implementing this new approach, several DCCM maps were calculated, each using a different coordinate reference frame from which protein domain boundaries and protein domain residue constituents could be identified. Cytochrome P450BM-3, from Bacillus megaterium, was used as the model protein in this study. The analyses indicated that the simulated protein comprises three distinct domain regions; in contrast, only two protein domains were identified in the original crystal structure report. Specifically, the DCCM analyses showed that the F-G helix region was a separate domain entity and not a part of the alpha domain, as previously designated. The simulations demonstrated that the domain motions of the F-G helix region effected both the size and shape of the enzyme active site, and that the dynamics of the F-G helix domain could possibly control access of substrate to the binding pocket.     

Mechanism of DnaB helicase of Escherichia coli: structural domains involved in ATP hydrolysis, DNA binding, and oligomerization.

We describe the delineation of three distinct structural domains of the DnaB helicase of Escherichia coli: domain alpha, amino acid residues (aa) 1-156; domain beta, aa 157-302; and domain gamma, aa 303-471. Using mutants with deletion in these domains, we have examined their role(s) in hexamer formation, DNA-dependent ATPase, and DNA helicase activities. The mutant DnaBbetagamma protein, in which domain alpha was deleted, formed a hexamer; whereas the mutant DnaBalphabeta, in which domain gamma was deleted, could form only dimers. The dimerization of DnaBalphabeta was Mg(2+) dependent. These data suggest that the oligomerization of DnaB helicase involves at least two distinct protein-protein interaction sites; one of these sites is located primarily within domain beta (site 1), while the other interaction site is located within domain gamma (site 2). The mutant DnaBbeta, a polypeptide of 147 aa, where both domains alpha and gamma were deleted, displayed a completely functional ATPase activity. This domain, thus, constitutes the "central catalytic domain" for ATPase activity. The ATPase activity of DnaBalphabeta was kinetically comparable to that of DnaBbeta, indicating that domain alpha had little or no influence on the ATPase activity. In both cases, the ATPase activities were DNA independent. DnaBbetagamma had a DNA-dependent ATPase activity that was kinetically comparable to the ATPase activity of wild-type DnaB protein (wtDnaB), indicating a specific role for C-terminal domain gamma in enhancement of the ATPase activity of domain beta as well as in DNA binding. Mutant DnaBbetagamma, which lacked domain alpha, was devoid of any helicase activity pointing to a significant role for domain alpha. The major findings of this study are (i) domain beta contained a functional ATPase active site; (ii) domain gamma appeared to be the DNA binding domain and a positive regulator of the ATPase activity of domain beta; (iii) although domain alpha did not have any significant effect on the ATPase, DNA binding activities, or hexamer formation, it definitely plays a pivotal role in transducing the energy of ATP hydrolysis to DNA unwinding by the hexamer; and (iv) all three domains are required for helicase activity.     

Dissection of the EntF condensation domain boundary and active site residues in nonribosomal peptide synthesis

Nonribosomal peptide synthetases (NRPSs) make many natural products of clinical importance, but a deeper understanding of the protein domains that compose NRPS assembly lines is required before these megasynthetases can be effectively engineered to produce novel drugs. The N-terminal amide bond-forming condensation (C) domain of the enterobactin NRPS EntF was excised from the multidomain synthetase using endpoints determined from sequence alignments and secondary structure predictions. The isolated domain was well-folded when compared by circular dichroism to the vibriobactin NRPS VibH, a naturally free-standing C domain. The EntF domain was also fully functional in an assay based on a synthetic small-molecule substrate, seryl N-acetylcysteamine. Active site mutants of the EntF C domain were surprisingly inactive in vitro as compared to their VibH counterparts, yet maintained the overall domain structure. An in vivo assay was developed in the context of the full-length EntF protein to more sensitively probe the activity level of the C domain mutants, and this supported strong effects for the active site mutations. The crucial role of histidine-138 was confirmed by assay of the full-length protein in vitro. These results suggest a strong resemblance of catalysis by the EntF C domain to chloramphenicol acetyltransferase, including an active site organized by an arginine-aspartate salt bridge, a key histidine acting as a general base, and an asparagine instead of a serine stabilizing the proposed tetrahedral intermediate by hydrogen bonding. The precise definition of a functional C domain excised from a NRPS should aid efforts at swapping NRPS domains between assembly lines.     

Stable Single α-Helices Are Constant Force Springs in Proteins

Single α-helix (SAH) domains are rich in charged residues (Arg, Lys, and Glu) and stable in solution over a wide range of pH and salt concentrations. They are found in many different proteins where they bridge two functional domains. To test the idea that their high stability might enable these proteins to resist unfolding along their length, the properties and unfolding behavior of the predicted SAH domain from myosin-10 were characterized. The expressed and purified SAH domain was highly helical, melted non-cooperatively, and was monomeric as shown by circular dichroism and mass spectrometry as expected for a SAH domain. Single molecule force spectroscopy experiments showed that the SAH domain unfolded at very low forces (<30 pN) without a characteristic unfolding peak. Molecular dynamics simulations showed that the SAH domain unfolds progressively as the length is increased and refolds progressively as the length is reduced. This enables the SAH domain to act as a constant force spring in the mechanically dynamic environment of the cell.     

Functional communications between the apical and equatorial domains of GroEL through the intermediate domain

The Escherichia coli GroEL subunit consists of three domains with distinct functional roles. To understand the role of each of the three domains, the effects of mutating a single residue in each domain (Y203C at the apical, T89W at the equatorial, and C138W at the intermediate domain) were studied in detail, using three different enzymes (enolase, lactate dehydrogenase, and rhodanese) as refolding substrates. By analyzing the effects of each mutation, a transfer of signals was detected between the apical domain and the equatorial domain. A signal initiated by the equatorial domain triggers the release of polypeptide from the apical domain. This trigger was independent of nucleotide hydrolysis, as demonstrated using an ATPase-deficient mutant, and, also, the conditions for successful release of polypeptide could be modified by a mutation in the apical domain, suggesting that the polypeptide release mechanism of GroEL is governed by chaperonin-target affinities. Interestingly, a reciprocal signal from the apical domain was suggested to occur, which triggered nucleotide hydrolysis in the equatorial domain. This signal was disrupted by a mutation in the intermediate domain to create a novel ternary complex in which GroES and refolding protein are simultaneously bound in a stable ternary complex devoid of ATPase activity. These results point to a multitude of signals which govern the overall chaperonin mechanism.     

Characterization of recombinant soluble macrophage scavenger receptor MARCO

MARCO is a type II transmembrane protein of the class A scavenger receptor family. It has a short N-terminal cytoplasmic domain, a transmembrane domain, and a large extracellular part composed of a 75-residue long spacer domain, a 270-residue collagenous domain, and a 99-residue long scavenger receptor cysteine-rich (SRCR) domain. Previous studies have indicated a role for this receptor in anti-microbial host defense functions. In this work we have produced the extracellular part of MARCO as a recombinant protein, and analyzed its binding properties. The production of this protein, soluble MARCO (sMARCO), has made it possible for the first time to study MARCO and its binding properties in a cell-free system. Using circular dichroism analyses, a protease-sensitive assay, and rotary shadowing electron microscopy, sMARCO was shown to have a triple-helical collagenous structure. Rotary shadowing also demonstrated that the molecules often associate with each other via the globes. sMARCO was found to bind avidly both heat-killed and living bacteria. Lipopolysaccharide, an important component of the outer membrane of Gram-negative bacteria, was shown to be a ligand of MARCO. Studies with different bacterial strains indicated that the O-side chain of lipopolysaccharide is not needed for the bacterial recognition. Finally, the C-terminal SRCR domain was also produced as a recombinant protein, and its bacteria-binding capability was studied. Although the transfection experiments with transmembrane MARCO variants have indicated a crucial role for this domain in bacterial binding, the monomeric domain exhibited low, barely detectable bacteria-binding activity. Thus, it is possible that cooperation between the SRCR domain and the collagenous domain is needed for high-affinity bacterial binding, or that the SRCR domain has to be in a trimeric form to effectively bind to bacteria.     

Interactions between the soluble domain I of nicotinamide nucleotide transhydrogenase from Rhodospirillum rubrum and transhydrogenase from Escherichia coli. Effects on catalytic and H+-pumping activities.

Nicotinamide nucleotide transhydrogenase from Escherichia coli is composed of two subunits, the alpha and the beta subunits, each of which contains a hydrophilic domain, domain I and III, respectively, as well as several transmembrane helices, collectively denoted domain II. The interactions between domain I from Rhodospirillum rubrum (rrI) and the intact or the protease-treated enzyme from E. coli was investigated using the separately expressed and purified domain I from R. rubrum, and His-tagged intact and trypsin-treated E. coli transhydrogenase. Despite harsh treatments with, e.g. detergents and denaturing agents, the alpha and beta subunits remained tightly associated. A monoclonal antibody directed towards the alpha subunit was strongly inhibitory, an effect that was relieved by added rrI. In addition, rrI also reactivated the trypsin-digested E. coli enzyme in which domain I had been partly removed. This suggests that the hydrophilic domains I and III are not in permanent contact but are mobile during catalysis while being anchored to domain II. Replacement of domain I of intact, as well as trypsin-digested, E. coli transhydrogenase with rrI resulted in a markedly different pH dependence of the cyclic reduction of 3-acetyl-pyridine-NAD+ by NADH in the presence of NADP(H), suggesting that the protonation of one or more protonable groups in domain I is controlling this reaction. The reverse reaction and proton pumping showed a less pronounced change in pH dependence, demonstrating the regulatory role of domain II in these reactions.