Formation of soluble inclusion bodies by hpv e6 oncoprotein fused to maltose-binding protein.

Many polypeptides overexpressed in bacteria are produced misfolded and accumulate as solid structures called inclusion bodies. Inclusion-body-prone proteins have often been reported to escape precipitation when fused to maltose-binding protein (MBP). Here, we have examined the case of HPV 16 oncoprotein E6. The unfused sequence of E6 is overexpressed as inclusion bodies in bacteria. By contrast, fusions of E6 to the C-terminus of MBP are produced soluble. We have analyzed preparations of soluble MBP-E6 fusions by using three independent approaches: dynamic light scattering, lateral turbidimetry, and sandwich ELISA. All three methods showed that MBP-E6 preparations contain highly aggregated material. The behavior of these soluble aggregates under denaturating conditions suggests that they are formed by agglomeration of misfolded E6 moieties. However, precipitation is prevented by the presence of the folded and highly soluble MBP moieties, which maintain the aggregates in solution. Therefore, the fact that a protein or protein domain is produced soluble when fused to the C-terminus of a carrier protein does not guarantee that the protein of interest is properly folded and active. We suggest that aggregation of fusion proteins should be systematically assayed, especially when these fusions are to be used for binding measurements or activity tests.

A strategy for optimizing the monodispersity of fusion proteins: application to purification of recombinant HPV E6 oncoprotein.

Recombinant production of HPV oncoprotein E6 is notoriously difficult. The unfused sequence is produced in inclusion bodies. By contrast, fusions of E6 to the C-terminus of carrier proteins such as maltose-binding protein or glutathione-S-transferase are produced soluble. However, it has not yet been possible to purify E6 protein from such fusion constructs. Here, we show that this was due to the biophysical heterogeneity of the fusion preparations. We find that soluble MBP-E6 preparations contain two subpopulations. A major fraction is aggregated and contains exclusively misfolded E6 moieties ('soluble inclusion bodies'). A minor fraction is monodisperse and contains the properly folded E6 moieties. Using monodispersity as a screening criterion, we optimized the expression conditions, the purification process and the sequence of E6, finally obtaining stable monodisperse MBP-E6 preparations. In contrast to aggregated MBP-E6, these preparations yielded fully soluble E6 after proteolytic removal of MBP. Once purified, these E6 proteins are stable, folded and biologically active. The first biophysical measurements on pure E6 were performed. This work shows that solubility is not a sufficient criterion to check that the passenger protein in a fusion construct is properly folded and active. By contrast, monodispersity appears as a better quality criterion. The monodispersity-based strategy presented here constitutes a general method to prepare fusion proteins with optimized folding and biological activity.

Structural and dynamic characterization of omega-conotoxin MVIIA: the binding loop exhibits slow conformational exchange.

omega-Conotoxin MVIIA is a 25-residue, disulfide-bridged polypeptide from the venom of the sea snail Conus magus that binds to neuronal N-type calcium channels. It forms a compact folded structure, presenting a loop between Cys8 and Cys15 that contains a set of residues critical for its binding. The loop does not have a unique defined structure, nor is it intrinsically flexible. Broadening of a subset of resonances in the NMR spectrum at low temperature, anomalous temperature dependence of the chemical shifts of some resonances, and exchange contributions to J(0) from (13)C relaxation measurements reveal that conformational exchange affects the residues in this loop. The effects of this exchange on the calculated structure of omega-conotoxin MVIIA are discussed. The exchange appears to be associated with a change in the conformation of the disulfide bridge Cys8-Cys20. The implications for the use of the omega-conotoxins as a scaffold for carrying other functions is discussed.

HPV oncoprotein E6 is a structure-dependent DNA-binding protein that recognizes four-way junctions.

E6 is an oncoprotein implicated in cervical cancers, produced by "high-risk" human papillomaviruses. E6 is thought to promote tumorigenesis by stimulating cellular degradation of the tumour suppressor p53, but it might display other activities. Sequence similarity was recently detected between E6 and endonuclease VII, a protein of phage T4 that recognizes and cleaves four-way DNA junctions. Here, we purified recombinant E6 proteins and demonstrated that high-risk E6 s bind selectively to four-way junctions in a structure-dependent manner. Several residues in the C-terminal zinc-binding domain, the region of E6 similar to endonuclease VII, are necessary for the junction-binding activity. E6 binds to the junction as a monomer. Comparative electrophoresis shows that E6-bound junctions migrate in an extended square conformation. Magnesium inhibits the electrophoretic migration of the complexes but does not seem to influence their formation at equilibrium. This work is the first demonstration of specific binding of purified active E6 to a well-characterized DNA ligand, and suggests new modes of action of E6 in oncogenesis.

Solution structure of a conformationally constrained Arg-Gly-Asp-like motif inserted into the alpha/beta scaffold of leiurotoxin I.

A monoclonal antibody, AC7, directed against the RGD-binding site of the GPIIIa subunit of the platelet fibrinogen receptor, interacts with activated platelet. The H3 region (H3, RQMIRGYFDV sequence) of the complementarity-determining region 3 heavy chain of AC7 inhibits platelet aggregation and fibrinogen binding to platelet. H3 contains the arginine, glycine and aspartate residues, but in an unusual order. The solution structure of the decapeptide has been studied by proton NMR. The NMR data suggested a helical equilibrium. To test whether the helical structure of H3 was biologically relevant, a conformationally constrained peptide with the RGD-like motif was designed. The sequence of a scorpion toxin (leiurotoxin I) has been modified in order to constrain the H3 sequence in a rigid helical conformation. The structure of leiurotoxin I consists of a beta-sheet and an alpha-helix, linked by three disulfide bridges. The structural feature of the chimeric peptide (H3-leiurotoxin) has been determined by standard two-dimensional NMR techniques. H3-Leiurotoxin structure closely resembles that of leiurotoxin I.

Refined solution structure and backbone dynamics of 15N-labeled C12A-p8MTCP1 studied by NMR relaxation.

MTCP1 (for Mature-T-Cell Proliferation) was the first gene unequivocally identified in the group of uncommon leukemias with a mature phenotype. The three-dimensional solution structure of the human p8MTCP1 protein encoded by the MTCP1 oncogene has been previously determined by homonuclear proton two-dimensional NMR methods at 600 MHz: it consists of an original scaffold comprising three alpha-helices, associated with a new cysteine motif. Two of the helices are covalently paired by two disulfide bridges, forming an alpha-hairpin which resembles an antiparallel coiled-coil. The third helix is orientated roughly parallel to the plane defined by the alpha-antiparallel motif and appears less well defined. In order to gain more insight into the details of this new scaffold, we uniformly labeled with nitrogen-15 a mutant of this protein (C12A-p8MTCP1) in which the unbound cysteine at position 12 has been replaced by an alanine residue, thus allowing reproducibly high yields of recombinant protein. The refined structure benefits from 211 additional NOEs, extracted from 15N-edited 3D experiments, and from a nearly complete set of phi angular restraints allowing the estimation of the helical content of the structured part of the protein. Moreover, measurements of 15N spin relaxation times and heteronuclear 15N¿1H¿NOEs provided additional insights into the dynamics of the protein backbone. The analysis of the linear correlation between J(0) and J(omega) was used to interpret relaxation parameters. It appears that the apparent relative disorder seen in helix III is not simply due to a lack of experimental constraints, but associated with substantial contributions of sub-nanosecond motions in this segment.

Reduced spectral density mapping for proteins: Validity for studies of 13C relaxation.

Spectral density mapping provides direct access to protein dynamics with no assumptions as to the nature of the molecule or its dynamic behaviour. Reduced spectral density mapping characterises a protein's motions at a lower experimental burden, assuming that the spectral density function J(ω) is flat around ωH. This introduces little error for 15N relaxation data but is less valid for 13C studies, perturbing J(ωC) considerably to an extent that depends on the nature of the molecule's motions. We propose the fitting of spectral density at high frequencies to a single Lorentzian and show that the true values of the spectral density lie between those determined by the two approximations.

Solution conformation of the synthetic bovine proenkephalin-A209-237 by 1H NMR spectroscopy.

Proenkephalin-A has been described to generate enkephalins, opoid peptides, and several derived peptides, which display various biological effects, including antinociception and immunological enhancement. Recently, we have isolated from bovine chromaffin granules a new antibacterial peptide, named enkelytin, which corresponds to the bisphosphorylated form of PEAP209-237 (Goumon, Y., Strub, J. M., Moniatte, M., Nullans, G., Poteur, L., Hubert, P., Van Dorsselaer, A., Aunis, D., and Metz-Boutigue, M. H. (1996) Eur. J. Biochem. 235, 516-525). In this paper, the three-dimensional solution structure of synthetic PEAP209-237 was investigated by NMR. These studies indicate that this peptide, which is unstructured in water, folds into an alpha-helical structure in trifluoroethanol/water (1/1). NMR data revealed two possible three-dimensional models of PEAP209-237. In both models, the proline residue Pro-227 induces a 90 degrees hinge between two alpha-helical segments (Ser-215 to Ser-221 and Glu-228 to Arg-232) leading to an overall L-shaped structure for the molecule. The negative charge of PEAP209-237 and the low amphipathy of the two alpha-helical segments imply new mechanisms to explain the antibacterial activity of enkelytin.

Bacterial iron transport: 1H NMR determination of the three-dimensional structure of the gallium complex of pyoverdin G4R, the peptidic siderophore of Pseudomonas putida G4R.

Among the fluorescent Pseudomonas species, Pseudomonas putida is a rare case of a nitrogen-fixing bacterium that transforms nitrogen into ammonia. When grown under iron-deficient conditions, it produces two major pyoverdins: pyoverdin G4R and pyoverdin G4RA. Their primary structures have been established using FAB-MS and one- and two-dimensional 15N, 13C, and 1H NMR on both the unlabeled and 15N-labeled compounds [Salah El Din, A. L. M., et al. (1997) Tetrahedron 53, 12539-12552]. The two pyoverdins have a common chromophore derived from 2,3-diamino-6,7-dihydroxyquinoline. The chromophore is bound to the linear heptapeptide L-Asp-L-Orn-D-beta-threo-OHAsp-L-Dab-Gly-L-Ser-L-cyclo-OHOrn . Circular dichroism spectra suggest that the absolute configuration of the metal complex is Delta. The three-dimensional structure in solution of pyoverdin G4R-Ga(III) was determined after interpretation of two-dimensional 1H NMR spectra recorded at 283 and 303 K. The complex is tightly defined with a compact structure with a Delta absolute configuration. The site of complexation of the metal ion is found to be located on the surface of the molecule, showing that the ion can be released without large conformational changes, while the polar groups of the peptide chain, which may be responsible for the recognition of the receptor, are placed on the opposite side of the overall shape. The three-dimensional structure of pyoverdin G4R-Ga(III) is compared with those of other pyoverdins, and the role of the structure in iron uptake is discussed.

The assembly of immunoglobulin-like modules in titin: implications for muscle elasticity.

Titin, a giant muscle protein, forms filaments that span half of the sarcomere and cover, along their length, quite diversified functions. The region of titin located in the sarcomere I-band is believed to play a major rôle in extensibility and passive elasticity of muscle. In the I-band, the titin sequence contains tandem immunoglobulin-like (Ig) modules intercalated by a potentially non-globular region. By a combined approach making use of small angle X-ray scattering and nuclear magnetic resonance techniques, we have addressed the questions of what are the average mutual orientation of poly-Igs and the degree of flexibility around the domain interfaces. Various recombinant fragments containing one, two and four titin I-band tandem domains were analysed. The small-angle scattering data provide a picture of the domains in a mostly extended configuration with their long axes aligned head-to-tail. There is a small degree of bending and twisting of the modules with respect to each other that results in an overall shortening in their maximum linear dimension compared with that expected for the fully extended, linear configurations. This shortening is greatest for the four module construct ( approximately 15%). 15N NMR relaxation studies of one and two-domain constructs show that the motions around the interdomain connecting regions are restricted, suggesting that titin behaves as a row of beads connected by rigid hinges. The length of the residues in the interface seems to be the major determinant of the degree of flexibility. Possible implications of our results for the structure and function of titin in muscles are discussed.

Characterization of antibacterial COOH-terminal proenkephalin-A-derived peptides (PEAP) in infectious fluids. Importance of enkelytin, the antibacterial PEAP209-237 secreted by stimulated chromaffin cells.

Proenkephalin-A (PEA) and its derived peptides (PEAP) have been described in neural, neuroendocrine tissues and immune cells. The processing of PEA has been extensively studied in the adrenal medulla chromaffin cell showing that maturation starts with the removal of the carboxyl-terminal PEAP209-239. In 1995, our laboratory has shown that antibacterial activity is present within the intragranular chromaffin granule matrix and in the extracellular medium following exocytosis. More recently, we have identified an intragranular peptide, named enkelytin, corresponding to the bisphosphorylated PEAP209-237, that inhibits the growth of Micrococcus luteus (Goumon, Y., Strub, J. M., Moniatte, M., Nullans, G., Poteur, L., Hubert, P., Van Dorsselaer, A., Aunis, D., and Metz-Boutigue, M. H. (1996) Eur. J. Biochem. 235, 516-525). As a continuation of this previous study, in order to characterize the biological function of antibacterial PEAP, we have here examined whether this COOH-terminal fragment is released from stimulated chromaffin cells and whether it could be detected in wound fluids and in polymorphonuclear secretions following cell stimulation. The antibacterial spectrum shows that enkelytin is active against several Gram-positive bacteria including Staphylococcus aureus, but it is unable to inhibit the Gram-negative bacteria growth. In order to relate the antibacterial activity of enkelytin with structural features, various synthetic enkelytin-derived peptides were tested. We also propose a computer model of synthetic PEAP209-237 deduced from 1H NMR analysis, in order to relate the antibacterial activity of enkelytin with the three-dimensional structure. Finally, we report the high phylogenetic conservation of the COOH-terminal PEAP, which implies some important biological function and we discuss the putative importance of enkelytin in the defensive processes.

Alpha-helix mimicry of a beta-turn.

It is shown here that the three-dimensional arrangement of the amino acids in an RGDF beta-turn (sequence involved in cell adhesion) resembles that of an alpha-helix with a shuffled RGDF sequence (i.e. RGXFD). A miniprotein was designed and constructed which arranges the RGXFD sequence into a well defined helical conformation. The designed protein is bioactive and folds into the desired structure as assessed by nuclear magnetic resonance spectroscopy. The recognition process mediated by a beta-turn can thus be mimicked by an alpha-helix.

Solution structure of PMP-C: a new fold in the group of small serine proteinase inhibitors.

The solution structure and the disulfide pairings of a 36-residue proteinase inhibitor isolated from the insect Locusta migratoria have been determined using NMR spectroscopy and simulated annealing calculations. The peptide, termed PMP-C, was previously shown to inhibit bovine alpha-chymotrypsin as well as human leukocyte elastase, and was also found to block high-voltage-activated Ca2+ currents in rat sensory neurones. PMP-C has a prolate ellipsoid shape and adopts a tertiary fold hitherto unobserved in the large group of small "canonical" proteinase inhibitors. The over-all fold consists mainly of three strands arranged in a right-handed twisted, antiparallel, beta-sheet that demarcates a cavity, together with a linear amino-terminal segment oriented almost perpendicular to the three strands of the beta-sheet. Inside the cavity a phenyl ring constitutes the centre of a hydrophobic core. The proteinase binding loop is located in the carboxy-terminal part of the molecule, between two cysteine residues involved in disulfide bridges. Its conformation resembles that found in other small canonical proteinase inhibitors. A comparison of PMP-C structure with the recently published solution structure of the related peptide PMP-D2 shows that the most significant differences are complementary changes involved in the stabilization of similar folds. This comparison led us to review the structure of PMP-D2 and to identify two salt bridges in PMP-D2.

Internal mobility in the partially folded DNA binding and dimerization domains of GAL4: NMR analysis of the N-H spectral density functions.

The DNA binding domain (residues 1--65) of the yeast transcriptional activator GAL4 is only partially folded. While residues 10-41, the DNA recognition domain, form a well-defined structure in the free protein, the whole polypeptide folds up and dimerizes upon binding DNA. In order to describe the mobility of the protein, we have characterized the frequency spectrum of the motions of N-H bond vectors of GAL4(1-65) using a reduced spectral density mapping approach (an approximation of the full spectral density mapping technique) [Peng, J. W., & Wagner, G. (1992a) J. Magn. Reson. 98, 308-332; Peng. J. W., & Wagner, G. (1992b) Biochemistry 31, 8571-8586]. 15N spin-lattice relaxation [Rn(Nz)], spin-spin relaxation [Rn(Nx,y)], cross-relaxation [RN(Hz-->Nz)], two-spin order [RNH(2HzNz)], and antiphase [RNH(2HzNx,y)] rates were determined for 52 of the 65 backbone amide groups at 10 degrees C and ph 6.5 at 11.74 T. Calculations of the spectral density functions using a reduced set of RN(Nz),RN(Nx,y),RN(Hz-->Nz), and RNH(2HzNz) gave excellent agreement with those calculated using all six sets. The reduced method has the added advantage that the errant behavior seen at high field values is circumvented. A linear correlation was found between J(omega N) and J(0) with a limited and clearly defined range of J(0) values which defines the range of rates for internal motions in GAL4(1-65). It appears that all residues experience a combination of two movements: one of the overall tumbling (correlation time, 8.65 ns) and the other of fast internal fluctuations of the structure. The respective weights of these contributions vary with the primary sequence and faithfully mirror the secondary and tertiary elements of the protein. The position on the correlation line of J(omega N) versus J(0) indicates the amount of angular averaging relative to the overall motion of the protein. A spectral density function for internal motions can be described.

Stabilization of proteins by glycosylation examined by NMR analysis of a fucosylated proteinase inhibitor.

Here we investigate the effects of the naturally occurring threonine-linked L-fucose moiety on the structure, dynamics and stability of the proteinase inhibitor PMP-C (Pars intercerebralis major peptide C). The three-dimensional structure of PMP-C fucosylated on Thr 9 has been determined by NMR spectroscopy and simulated annealing. The fucose ring is very well ordered, held in place by hydrophobic and hydrogen bond interactions with Thr 16 and Arg 18. Comparing the NMR data and the structure of the fucosylated inhibitor with those of the nonfucosylated form shows that conformational changes only occur in the vicinity of the fucose moiety. Nevertheless, a comparative analysis of the exchange rates of amide protons indicates that fucosylation is responsible for an overall decrease of the dynamic fluctuations of the molecule. This correlates well with an increase in stability of approximately 1 kcal mol-1 as monitored by thermal denaturation.

Theory and practice of nuclear spin relaxation in proteins.

NMR relaxation experiments can provide information on overall and internal motions in proteins. This review consists of a concise report on the evolution of the theories for nuclear relaxation followed by an overview of mathematical models for internal motions in proteins. Next, the method of spectral density mapping with recent developments is reviewed. This is followed by a discussion of pulse sequences for relaxation experiments. Finally, we review recent studies correlating relaxation parameters, in particular spectral density functions, with structural features of proteins and with results of molecular dynamics simulations.

NMR data show that the carcinogen N-2-acetylaminofluorene stabilises an intermediate of -2 frameshift mutagenesis in a region of high mutation frequency.

The heteroduplex, D(ACCGGCGCCACA) . d(TGTGG-CCGGT), containing two bulged bases, a cytosine and the guanine G7, either unmodified or modified with the carcinogen N-2-acetylaminofluorene, have been studied by NMR as models of slipped-mutagenic intermediates (SMI). The melting temperature of the modified heteroduplex is strongly increased compared with that of the unmodified heteroduplex. NMR studies have shown that all the bases of the unmodified heteroduplex are stacked within the helix, without any disruption of the sequential connectivities. The two strands are in a B-like conformation. Nevertheless, exchangeable-proton studies have revealed that base pairing is very weak, or even lacking, over two base pairs apart from the bulge. Concerning the modified heteroduplex, no B-like connectivity is observed in the G5-C9 segment. Moreover, the cytosine C8 is rejected outside the helix, whereas the N-2-acetylaminofluorene moiety is inserted within the helix. The G5.C18, C6.G17 and C9.G16 bases are remarkably stable when the temperature is increased, in agreement with the high melting temperature. Some small unassigned peaks reveal the presence of the minor conformation in equilibrium. The strong stabilisation of the N-2-acetylaminofluorene-modified heteroduplex compared with the unmodified duplex is in agreement with the high N-2-acetylaminofluorene-induced mutation frequency compared with the spontaneous frequency and with the hypothesis of mutagenesis occurring during replication.

Solution structure of PMP-D2, a 35-residue peptide isolated from the insect Locusta migratoria.

The three-dimensional solution structure of PMP-D2, a 35 amino acid peptide isolated from the insect Locusta migratoria, has been determined from two-dimensional 1H NMR spectroscopy data. The structure calculations were performed from 222 NOE-derived interproton distances and 11 dihedral angles calculated from the JHN-H alpha coupling constants, using either a combination of distance geometry and restrained simulated annealing or by restrained simulated annealing alone. PMP-D2 contains three disulfide bridges that have been assigned from NMR data and structure calculations and independently confirmed using chemical and enzymatic methods. The core region of PMP-D2 adopts a compact globular fold, stabilized by hydrophobic interactions, which consists of a short three-stranded antiparallel beta-sheet involving residues 8-11, 15-19, and 25-29. Back-calculation of the NOESY spectra was used to validate the final structures. Analysis of the CD spectra of PMP-D2 under various conditions of ionic strength and in the presence of organic solvents demonstrates the high stability of this molecule. PMP-D2 was recently shown to inhibit Ca2+ currents. This activity is discussed based on the comparison of PMP-D2 three-dimensional structure with the recently established three-dimensional structure of the Ca2+ channel blocker omega-conotoxin GVIA.

NMR evidence of the stabilisation by the carcinogen N-2-acetylaminofluorene of a frameshift mutagenesis intermediate.

Two heteroduplexes d(C1A2C3T4C5G6C7A8C9A10C11)-d (G12T13G14T15G16G17A18G19T20G21) containing a bulged guanine either unmodified or modified with the carcinogen N-2-acetylaminofluorene (AAF) have been studied by nuclear magnetic resonance (NMR) as models of slipped mutagenic intermediates (SMI). Conformational equilibria are observed in both the unmodified and the AAF-modified heteroduplexes. The major conformation of the unmodified duplex is one where the extra guanine is stacked in the helix and the major conformation of the AAF-modified heteroduplex is one where the AAF is external to the helix. Unusual sugar proton chemical shifts of C5- and G6-AAF indicate that the AAF ring is pointing out in the 5' direction. A strong increase in the modified heteroduplex melting temperature (+15 degrees C) is observed. Moreover, in contrast to the unmodified heteroduplex, which shows extensive melting in the vicinity of the bulged guanine, the base pairs around the bulge in the AAF-modified heteroduplex remain paired at temperatures up to 30 degrees C. This exceptional stability of the site around the bulged modified guanine is suggested to be responsible for the high rate of -1 mutation induced by AAF at repetitive sequences.