Folding and stability of the isolated Greek key domains of the long-lived human lens proteins gammaD-crystallin and gammaS-crystallin

The transparency of the eye lens depends on the high solubility and stability of the lens crystallin proteins. The monomeric gamma-crystallins and oligomeric beta-crystallins have paired homologous double Greek key domains, presumably evolved through gene duplication and fusion. Prior investigation of the refolding of human gammaD-crystallin revealed that the C-terminal domain folds first and nucleates the folding of the N-terminal domain. This result suggested that the human N-terminal domain might not be able to fold on its own. We constructed and expressed polypeptide chains corresponding to the isolated N- and C-terminal domains of human gammaD-crystallin, as well as the isolated domains of human gammaS-crystallin. Both circular dichroism and fluorescence spectroscopy indicated that the isolated domains purified from Escherichia coli were folded into native-like monomers. After denaturation, the isolated domains refolded efficiently at pH 7 and 37 degrees C into native-like structures. The in vitro refolding of all four domains revealed two kinetic phases, identifying partially folded intermediates for the Greek key motifs. When subjected to thermal denaturation, the isolated N-terminal domains were less stable than the full-length proteins and less stable than the C-terminal domains, and this was confirmed in equilibrium unfolding/refolding experiments. The decrease in stability of the N-terminal domain of human gammaD-crystallin with respect to the complete protein indicated that the interdomain interface contributes of 4.2 kcal/mol to the overall stability of this very long-lived protein.     

Structural and functional analysis of ProQ: an osmoregulatory protein of Escherichia coli

Transporter ProP of Escherichia coli senses extracellular osmolality and responds by mediating cytoplasmic accumulation of organic solutes such as proline. Lesions at the proQ locus reduce ProP activity in vivo. ProQ was previously purified and characterized. Homology modeling predicted that ProQ possesses an alpha-helical N-terminal domain (residues 1-130) and a beta-sheet C-terminal domain (residues 181-232) connected by an unstructured linker. In this work, we tested the structural model for ProQ, explored the solubility and folding of full length ProQ and its domains in diverse buffers, and tested the impacts of the putative ProQ domains on ProP activity in vivo. Limited tryptic proteolysis of ProQ revealed protease resistant fragments corresponding to the predicted N-terminal and C-terminal domains. Polypeptides corresponding to the predicted N- and C-terminal domains could be overexpressed and purified to near homogeneity using nickel affinity, size exclusion and reversed phase chromatographies. Circular dichroism spectroscopy of the purified proteins revealed that the N-terminal domain was predominantly alpha-helical, whereas the C-terminal domain was predominantly beta-sheet, as predicted. The domains were soluble and folded in neutral buffers containing 0.6 M NaCl. The N-terminal domain was soluble and folded in 0.1 M MES (2-[N-morpholino]-ethane sulfonic acid) at pH 5.6. Despite high solubilities, the proteins were not well folded in Na citrate (0.1 M, pH 2.3). The ProQ domains and the linker were expressed at physiological levels, singly and in combination, in bacteria lacking the chromosomal proQ locus. Among these proteins, the N-terminal domain could partially complement the proQ deletion. The full length protein and a variant lacking only the linker restored full activity of the ProP protein.     

Autodisplay: functional display of active beta-lactamase on the surface of Escherichia coli by the AIDA-I autotransporter

Members of the protein family of immunoglobulin A1 protease-like autotransporters comprise multidomain precursors consisting of a C-terminal autotransporter domain that promotes the translocation of N-terminally attached passenger domains across the cell envelopes of gram-negative bacteria. Several autotransporter domains have recently been shown to efficiently promote the export of heterologous passenger domains, opening up an effective tool for surface display of heterologous proteins. Here we report on the autotransporter domain of the Escherichia coli adhesin involved in diffuse adherence (AIDA-I), which was genetically fused to the C terminus of the periplasmic enzyme beta-lactamase, leading to efficient expression of the fusion protein in E. coli. The beta-lactamase moiety of the fusion protein was presented on the bacterial surface in a stable manner, and the surface-located beta-lactamase was shown to be enzymatically active. Enzymatic activity was completely removed by protease treatment, indicating that surface display of beta-lactamase was almost quantitative. The periplasmic domain of the outer membrane protein OmpA was not affected by externally added proteases, demonstrating that the outer membranes of E. coli cells expressing the beta-lactamase AIDA-I fusion protein remained physiologically intact.     

Regulatory domains of Snf1-activating kinases determine pathway specificity

In Saccharomyces cerevisiae, the Snf1 kinase can be activated by any one of three upstream kinases, Sak1, Tos3, or Elm1. All three Snf1-activating kinases contain serine/threonine kinase domains near their N termini and large C-terminal domains with little sequence conservation and previously unknown function. Deletion of the C-terminal domains of Sak1 and Tos3 greatly reduces their ability to activate the Snf1 pathway. In contrast, deletion of the Elm1 C-terminal domain has no effect on Snf1 signaling but abrogates the ability of Elm1 to participate in the morphogenetic-checkpoint signaling pathway. Thus, the C-terminal domains of Sak1, Tos3, and Elm1 help to determine pathway specificity. Additional deletion mutants of the Sak1 kinase revealed that the N terminus of the protein is essential for Snf1 signaling. The deletion of 43 amino acids from within the N terminus of Sak1 (residues 87 to 129) completely blocks Snf1 signaling and activation loop phosphorylation in vivo. The Sak1 kinase domain (lacking both N-terminal and C-terminal domains) is catalytically active and specific in vitro but is unable to promote Snf1 signaling in vivo when expressed at normal levels. Our studies indicate that the kinase domains of the Snf1-activating kinases are not sufficient by themselves for their proper function and that the nonconserved N-terminal and C-terminal domains are critical for the biological activities of these kinases.     

Folding of the multidomain ribosomal protein L9: the two domains fold independently with remarkably different rates

The folding and unfolding behavior of the multidomain ribosomal protein L9 from Bacillus stearothermophilus was studied by a novel combination of stopped-flow fluorescence and nuclear magnetic resonance (NMR) spectroscopy. One-dimensional 1H spectra acquired at various temperatures show that the C-terminal domain unfolds at a lower temperature than the N-terminal domain (Tm = 67 degrees C for the C-terminal domain, 80 degrees C for the N-terminal domain). NMR line-shape analysis was used to determine the folding and unfolding rates for the N-terminal domain. At 72 degrees C, the folding rate constant equals 2980 s-1 and the unfolding rate constant equals 640 s-1. For the C-terminal domain, saturation transfer experiments performed at 69 degrees C were used to determine the folding rate constant, 3.3 s-1, and the unfolding rate constant, 9.0 s-1. Stopped-flow fluorescence experiments detected two resolved phases: a fast phase for the N-terminal domain and a slow phase for the C-terminal domain. The folding and unfolding rate constants determined by stopped-flow fluorescence are 760 s-1 and 0.36 s-1, respectively, for the N-terminal domain at 25 degrees C and 3.0 s-1 and 0.0025 s-1 for the C-terminal domain. The Chevron plots for both domains show a V-shaped curve that is indicative of two-state folding. The measured folding rate constants for the N-terminal domain in the intact protein are very similar to the values determined for the isolated N-terminal domain, demonstrating that the folding kinetics of this domain is not affected by the rest of the protein. The remarkably different rate constants between the N- and C-terminal domains suggest that the two domains can fold and unfold independently. The folding behavior of L9 argues that extremely rapid folding is not necessarily functionally important.     

Tolerance for random recombination of domains in prokaryotic and eukaryotic translation systems: Limited interdomain misfolding in a eukaryotic translation system

It has been proposed that eukaryotic translation systems have a greater capacity for cotranslational folding of domains than prokaryotic translation systems, which reduces interdomain misfolding in multidomain proteins and, therefore, leads to tolerance for random recombination of domains. However, there has been a controversy as to whether prokaryotic and eukaryotic translation systems differ in the capacity for cotranslational domain folding. Here, to examine whether these systems differ in the tolerance for the random domain recombination, we systematically combined six proteins, out of which four are soluble and two are insoluble when produced in an Escherichia coli and a wheat germ cell-free protein synthesis systems, to construct a fusion protein library. Forty out of 60 two-domain proteins and 114 out of 120 three-domain proteins were more soluble when produced in the wheat system than in the E. coli system. Statistical analyses of the solubilities and the activities indicated that, in the wheat system but not in the E. coli system, the two soluble domains comprised mainly of beta-sheets tend to avoid interdomain misfolding and to fold properly even at the neighbor of the misfolded domains. These results demonstrate that a eukaryotic system permits the concomitance of a wider variety of domains within a single polypeptide chain than a prokaryotic system, which is probably due to the difference in the capacity for cotranslational folding. This difference is likely to be related to the postulated difference in the tolerance for random recombination of domains.     

Functional analysis of the C-terminal region of γ-glutamyl kinase of Saccharomyces cerevisiae

γ-Glutamyl kinase (GK) is the rate-limiting enzyme in proline synthesis in microorganisms. Most microbial GKs contain an N-terminal kinase domain and a C-terminal pseudouridine synthase and archaeosine transglycosylase (PUA) domain. In contrast, higher eukaryotes possess a bifunctional Δ(1)-pyrroline-5-carboxylate synthetase, which consists of a PUA-free GK domain and a γ-glutamyl phosphate reductase (GPR) domain. Here, to examine the role of the C-terminal region, including the PUA domain of Saccharomyces cerevisiae GK, we constructed a variety of truncated yeast GK and GK/GPR fusion proteins from which the C-terminal region was deleted. A complementation test in Escherichia coli and S. cerevisiae and enzymatic analysis of recombinant proteins revealed that a 67-residue linker sequence between a 255-residue kinase domain and a 106-residue PUA domain is essential for GK activity. It also appeared that 67 or more residues of the C-terminal region, not the PUA domain itself, are required for the full display of GK activity. Further, the GK/GPR fusion protein was functional in E. coli, but decreased stability and Mg-binding ability as compared to wild-type GK. These results suggest that the C-terminal region of S. cerevisiae GK is involved in the folding and/or the stability of the kinase domain.     

Functional domains of theEscherichia coli ferric uptake regulator protein (Fur)

The functions of N- and C-terminal domains of the Fur repressor ofEscherichia coli in promoter recognition and dimerization were studied. We investigated the ability of fusion proteins containing the N- or C-terminal domain of Fur to dimerize and to repress a Fur-regulatedlacZ fusion gene. The N-terminal domain, when fused to the C-terminal domain of the repressor C1857, repressed a Fur-regulatedlacZ fusion. However, the Fur-CI857 fusion was unable to complement the growth defect of anE. coli fur mutant on fumarate and succinate. The C-terminal domain of Fur, when fused to the N-terminus of CI857, repressed a λP, -regulatedlacZ fusion, indicating dimerization of the chimeric protein, which is a prerequisite for Cl activity. Both fusion proteins were fully active under both iron-rich and iron-poor growth conditions. We conclude that the N-terminal domain of Fur is involved in recognition of the Fur-responsive promoter and the C-terminus mediates oligomerization of the repressor.     

Extra terminal residues have a profound effect on the folding and solubility of a Plasmodium falciparum sexual stage-specific protein over-expressed in Escherichia coli.

The presence of extra N- and C- terminal residues can play a major role in the stability, solubility and yield of recombinant proteins. Pfg27 is a 27K soluble protein that is essential for sexual development in Plasmodium falciparum. It was over-expressed using the pMAL-p2 vector as a fusion protein with the maltose binding protein. Six different constructs were made and each of the fusion proteins were expressed and purified. Our results show that the fusion proteins were labile and only partially soluble in five of the constructs resulting in very poor yields. Intriguingly, in the sixth construct, the yield of soluble fusion protein with an extended carboxyl terminus of 17 residues was several fold higher. Various constructs with either N-terminal or smaller C-terminal extensions failed to produce any soluble fusion protein. Furthermore, all five constructs produced Pfg27 that precipitated after protease cleavage from its fusion partner. The sixth construct, which produced soluble protein in high yields, also gave highly stable and soluble Pfg27 after cleavage of the fusion. These results indicate that extra amino acid residues at the termini of over-expressed proteins can have a significant effect on the folding of proteins expressed in E. coli. Our data suggest the potential for development of a novel methodology, which will entail construction of fusion proteins with maltose binding protein as a chaperone on the N-terminus and a C-terminal 'solubilization tag'. This system may allow large-scale production of those proteins that have a tendency to misfold during expression.     

Expression in Escherichia coli of N- and C-terminally deleted human holocarboxylase synthetase. Influence of the N-terminus on biotinylation and identification of a minimum functional protein

Biotin functions as a covalently bound cofactor of biotindependent carboxylases. Biotin attachment is catalyzed by biotin protein ligases, called holocarboxylase synthetase in mammals and BirA in prokaryotes. These enzymes show a high degree of sequence similarity in their biotinylation domains but differ markedly in the length and sequence of their N terminus. BirA is also the repressor of the biotin operon, and its DNA attachment site is located in its N terminus. The function of the eukaryotic N terminus is unknown. Holocarboxylase synthetase with N- and C-terminal deletions were evaluated for the ability to catalyze biotinylation after expression in Escherichia coli using bacterial and human acceptor substrates. We showed that the minimum functional protein is comprised of the last 349 of the 726-residue protein, which includes the biotinylation domain. Significantly, enzyme containing intermediate length, N-terminal deletions interfered with biotin transfer and interaction with different peptide acceptor substrates. We propose that the N terminus of holocarboxylase synthetase contributes to biotinylation through N- and C-terminal interactions and may affect acceptor substrate recognition. Our findings provide a rationale for the biotin responsiveness of patients with point mutations in the N-terminal sequence of holocarboxylase synthetase. Such mutant enzyme may respond to biotin-mediated stabilization of the substrate-bound complex.     

Structural similarities in the noncatalytic domains of phenylalanyl-tRNA and biotin synthetases.

Detailed comparison between the structures of the Escherichia coli biotin synthetase/repressor protein (BirA) and the recently solved Thermus thermophilus phenylalanyl-tRNA synthetase (PheRS) reveals significant similarities outside their respective catalytic domains. These comprise a DNA-binding alpha+beta domain and an Src-homology 3 (SH3)-like domain that were observed in both enzymes. This similarity provides a novel example in which all domains of one multidomain protein appear to be constituents of the other multidomain protein and supports a concept of a common ancestor for two different synthetase families.     

Functional domains of theEscherichia coli ferric uptake regulator protein (Fur)

The functions of N- and C-terminal domains of the Fur repressor ofEscherichia coli in promoter recognition and dimerization were studied. We investigated the ability of fusion proteins containing the N- or C-terminal domain of Fur to dimerize and to repress a Fur-regulatedlacZ fusion gene. The N-terminal domain, when fused to the C-terminal domain of the repressor C1857, repressed a Fur-regulatedlacZ fusion. However, the Fur-CI857 fusion was unable to complement the growth defect of anE. coli fur mutant on fumarate and succinate. The C-terminal domain of Fur, when fused to the N-terminus of CI857, repressed a P, -regulatedlacZ fusion, indicating dimerization of the chimeric protein, which is a prerequisite for Cl activity. Both fusion proteins were fully active under both iron-rich and iron-poor growth conditions. We conclude that the N-terminal domain of Fur is involved in recognition of the Fur-responsive promoter and the C-terminus mediates oligomerization of the repressor.     

A system using convertible vectors for screening soluble recombinant proteins produced in Escherichia coli from randomly fragmented cDNAs

Protein insolubility is a major problem when producing recombinant proteins (e.g., to be used as antigens) from large cDNAs in Escherichia coli. Here, we describe a system using three convertible plasmid vectors to screen for soluble proteins produced in E. coli. This system experimentally identified any random cDNA fragments producing soluble protein domains. Shotgun fragments introduced into any of our three plasmids, which contain Gateway recombination sites, fused in-frame to the ORF of the protein tag. These plasmids produced N-terminal GST- and C-terminal three-frame-adaptive FLAG-tagged proteins, kanamycin-resistant gene-tagged proteins (which were pre-selected for in-frame fused cDNAs), or GFP-tagged fusion proteins. The latter is useful as a fluorescence indicator of protein folding. The Gateway recombination sites promote smooth conversion for enrichment of in-frame clones and facilitate both protein solubility assays and final production of proteins without the C-terminal tag. This high-throughput screening method is particularly useful for procedures that require the handling of many cDNAs in parallel.     

The UDP-glucose:glycoprotein glucosyltransferase is organized in at least two tightly bound domains from yeast to mammals

The endoplasmic reticulum UDP-Glc:glycoprotein glucosyltransferase (GT) exclusively glucosylates nonnative glycoprotein conformers. GT sequence analysis suggests that it is composed of at least two domains: the N-terminal domain, which composes 80% of the molecule, has no significant similarity to other known proteins and was proposed to be involved in the recognition of non-native conformers and the C-terminal or catalytic domain, which displays a similar size and significant similarity to members of glycosyltransferase family 8. Here, we show that N- and C-terminal domains from Rattus norvegicus and Schizosaccharomyces pombe GTs remained tightly but not covalently bound upon a mild proteolytic treatment and could not be separated without loss of enzymatic activity. The notion of a two-domain protein was reinforced by the synthesis of an active enzyme upon transfection of S. pombe GT null mutants with two expression vectors, each of them encoding one of both domains. Transfection with the C-terminal domain-encoding vector alone yielded an inactive, rapidly degraded protein, thus indicating that the N-terminal domain is required for proper folding of the C-terminal catalytic portion. If, indeed, the N-terminal domain is, as proposed, also involved in glycoprotein conformation recognition, the tight association between N- and C-terminal domains may explain why only N-glycans in close proximity to protein structural perturbations are glucosylated by the enzyme. Although S. pombe and Drosophila melanogaster GT N-terminal domains display an extremely poor similarity (16.3%), chimeras containing either yeast N-terminal and fly C-terminal domains or the inverse construction were enzymatically and functionally active in vivo, thus indicating that the N-terminal domains of both GTs shared three-dimensional features.     

Knotted fusion proteins reveal unexpected possibilities in protein folding

Proteins that contain a distinct knot in their native structure are impressive examples of biological self-organization. Although this topological complexity does not appear to cause a folding problem, the mechanisms by which such knotted proteins form are unknown. We found that the fusion of an additional protein domain to either the amino terminus, the carboxy terminus, or to both termini of two small knotted proteins did not affect their ability to knot. The multidomain constructs remained able to fold to structures previously thought unfeasible, some representing the deepest protein knots known. By examining the folding kinetics of these fusion proteins, we found evidence to suggest that knotting is not rate limiting during folding, but instead occurs in a denatured-like state. These studies offer experimental insights into when knot formation occurs in natural proteins and demonstrate that early folding events can lead to diverse and sometimes unexpected protein topologies.     

Effects of the N-terminal and C-terminal domains of <Emphasis Type="Italic">Meiothermus ruber</Emphasis> CBS-01 trehalose synthase on thermostability and activity

Numerous trehalose synthases (TreS) from thermophilic microorganisms have extra C-terminal domains. To determine the function of the N- and C-terminal domains of TreS from the thermophilic bacterium Meiothermus ruber CBS-01, the two domains were expressed. From the findings, the N-terminal domain from M. ruber was not active when compared with that from Thermus thermophilus, which had been studied previously. The circular dichroism spectrum showed that the secondary structure of N-terminal domain from M. ruber underwent a greater change than that of C terminus. In addition, the N-terminal domain from T. thermophilus and C terminus from M. ruber were fused. The fusion protein TSTtMr was more efficient and thermostable than the TreS from M. ruber. The N-terminal domain from M. ruber and C terminus from T. thermophilus were fused. The optimum temperature and thermostability of fusion protein TSMrTt were similar to the TreS from M. ruber. It was presumed that aside from the C-terminal domain, the N-terminal domain of TreS from thermophilic bacteria could influence thermostability. For the TreS from M. ruber, the mutant protein R392F led to a complete loss in activity, and R392A showed a sharp decrease in activity.     

The Ability to Enhance the Solubility of Its Fusion Partners Is an Intrinsic Property of Maltose-Binding Protein but Their Folding Is Either Spontaneous or Chaperone-Mediated

Escherichia coli maltose binding protein (MBP) is commonly used to promote the solubility of its fusion partners. To investigate the mechanism of solubility enhancement by MBP, we compared the properties of MBP fusion proteins refolded in vitro with those of the corresponding fusion proteins purified under native conditions. We fused five aggregation-prone passenger proteins to 3 different N-terminal tags: His₆-MBP, His₆-GST and His₆. After purifying the 15 fusion proteins under denaturing conditions and refolding them by rapid dilution, we recovered far more of the soluble MBP fusion proteins than their GST- or His-tagged counterparts. Hence, we can reproduce the solubilizing activity of MBP in a simple in vitro system, indicating that no additional factors are required to mediate this effect. We assayed both the soluble fusion proteins and their TEV protease digestion products (i.e., with the N-terminal tag removed) for biological activity. Little or no activity was detected for some fusion proteins whereas others were quite active. When the MBP fusions proteins were purified from E. coli under native conditions they were all substantially active. These results indicate that the ability of MBP to promote the solubility of its fusion partners in vitro sometimes, but not always, results in their proper folding. We show that the folding of some passenger proteins is mediated by endogenous chaperones in vivo. Hence, MBP serves as a passive participant in the folding process; passenger proteins either fold spontaneously or with the assistance of chaperones.     

Chimeras between single-stranded DNA-binding proteins from Escherichia coli and Mycobacterium tuberculosis reveal that their C-terminal domains interact with uracil DNA glycosylases

Uracil, a promutagenic base in DNA can arise by spontaneous deamination of cytosine or incorporation of dUMP by DNA polymerase. Uracil is removed from DNA by uracil DNA glycosylase (UDG), the first enzyme in the uracil excision repair pathway. We recently reported that the Escherichia coli single-stranded DNA binding protein (SSB) facilitated uracil excision from certain structured substrates by E. coli UDG (EcoUDG) and suggested the existence of interaction between SSB and UDG. In this study, we have made use of the chimeric proteins obtained by fusion of N- and C-terminal domains of SSBs from E. coli and Mycobacterium tuberculosis to investigate interactions between SSBs and UDGs. The EcoSSB or a chimera containing its C-terminal domain interacts with EcoUDG in a binary (SSB-UDG) or a ternary (DNA-SSB-UDG) complex. However, the chimera containing the N-terminal domain from EcoSSB showed no interactions with EcoUDG. Thus, the C-terminal domain (48 amino acids) of EcoSSB is necessary and sufficient for interaction with EcoUDG. The data also suggest that the C-terminal domain (34 amino acids) of MtuSSB is a predominant determinant for mediating its interaction with MtuUDG. The mechanism of how the interactions between SSB and UDG could be important in uracil excision repair pathway has been discussed.     

Distribution and function of new bacterial intein-like protein domains

Hint protein domains appear in inteins and in the C-terminal region of Hedgehog and Hedgehog-like animal developmental proteins. Intein Hint domains are responsible and sufficient for protein-splicing of their host-protein flanks. In Hedgehog proteins the Hint domain autocatalyses its cleavage from the N-terminal domain of the Hedgehog protein by attaching a cholesterol molecule to it. We identified two new types of Hint domains. Both types have active site sequence features of Hint domains but also possess distinguishing sequence features. The new domains appear in more than 50 different proteins from diverse bacteria, including pathogenic species of humans and plants, such as Neisseria meningitidis and Pseudomonas syringae. These new domains are termed bacterial intein-like (BIL) domains. Bacterial intein-like domains are present in variable protein regions and are typically flanked by domains that also appear in secreted proteins such as filamentous haemagglutinin and calcium binding RTX repeats. Phylogenetic and genomic analysis of BIL sequences suggests that they were positively selected for in different lineages. We cloned two BIL domains of different types and showed them to be active. One of the domains efficiently cleaved itself from its C-terminal flank and could also protein-splice its two flanks, in E. coli and in a cell free system. We discuss several possible biological roles for BIL domains including microevolution and post translational modification for generating protein variability.