Iron-mineral accretion from acid mine drainage and its application in passive treatment.

This study demonstrates substantial removal of iron (Fe) from acid mine drainage (pH ≈3) in a passive vertical flow reactor (VFR) with an equivalent footprint of 154 m(2) per L/s mine water and residence times of >23 h. Average Fe removal rate was 67% with a high of 85% over the 10-month trial. The fraction of Fe passing a 0.22 µm filter (referred to here as Fe-filt) was seen to be removed in the VFR even when Fe(II) was absent, indicating that the contribution of microbial Fe(II) oxidation and precipitation was not the dominant removal mechanism in the VFR. Removal rates of Fe-filt in the VFR were up to 70% in residence times as low as 8 h compared with laboratory experiments where much smaller changes in Fe-filt were observed over 60 h. Centrifugation indicated that 80-90% of the influent Fe had particle sizes <35 nm. Together with analyses and geochemical modelling, this suggests that the Fe-filt fraction exists as either truly aqueous (but oversaturated) Fe(III) or nanoparticulate Fe(III) and that this metastability persists. When the water was contacted with VFR sludge, the Fe-filt fraction was destabilized, leading to an appreciably higher removal of this fraction. Heterogeneous precipitation and/or aggregation of nanoparticulate Fe(III) precipitates are considered predominant removal mechanisms. Microbial analyses of the mine water revealed the abundance of extracellular polymeric substance-generating Fe-oxidizing bacterium 'Ferrovum myxofaciens', which may aid the removal of iron and explain the unusual appearance and physical properties of the sludge.

Antifreeze protein from shorthorn sculpin: identification of the ice-binding surface.

Shorthorn sculpins, Myoxocephalus scorpius, are protected from freezing in icy seawater by alanine-rich, alpha-helical antifreeze proteins (AFPs). The major serum isoform (SS-8) has been reisolated and analyzed to establish its correct sequence. Over most of its length, this 42 amino acid protein is predicted to be an amphipathic alpha-helix with one face entirely composed of Ala residues. The other side of the helix, which is more heterogeneous and hydrophilic, contains several Lys. Computer simulations had suggested previously that these Lys residues were involved in binding of the peptide to the [11-20] plane of ice in the <-1102> direction. To test this hypothesis, a series of SS-8 variants were generated with single Ala to Lys substitutions at various points around the helix. All of the peptides retained significant alpha-helicity and remained as monomers in solution. Substitutions on the hydrophilic helix face at position 16, 19, or 22 had no obvious effect, but those on the adjacent Ala-rich surface at positions 17, 21, and 25 abolished antifreeze activity. These results, with support from our own modeling and docking studies, show that the helix interacts with the ice surface via the conserved alanine face, and lend support to the emerging idea that the interaction of fish AFPs with ice involves appreciable hydrophobic interactions. Furthermore, our modeling suggests a new N terminus cap structure, which helps to stabilize the helix, whereas the role of the lysines on the hydrophilic face may be to enhance solubility of the protein.

Gonococcal MinD affects cell division in Neisseria gonorrhoeae and Escherichia coli and exhibits a novel self-interaction.

The Min proteins are involved in determining cell division sites in bacteria and have been studied extensively in rod-shaped bacteria. We have recently shown that the gram-negative coccus Neisseria gonorrhoeae contains a min operon, and the present study investigates the role of minD from this operon. A gonococcal minD insertional mutant, CJSD1, was constructed and exhibited both grossly abnormal cell division and morphology as well as altered cell viability. Western blot analysis verified the absence of MinD from N. gonorrhoeae (MinD(Ng)) in this mutant. Hence, MinD(Ng) is required for maintaining proper cell division and growth in N. gonorrhoeae. Immunoblotting of soluble and insoluble gonococcal cell fractions revealed that MinD(Ng) is both cytosolic and associated with the insoluble membrane fraction. The joint overexpression of MinC(Ng) and MinD(Ng) from a shuttle vector resulted in a significant enlargement of gonococcal cells, while cells transformed with plasmids encoding either MinC(Ng) or MinD(Ng) alone did not display noticeable morphological changes. These studies suggest that MinD(Ng) is involved in inhibiting gonococcal cell division, likely in conjunction with MinC(Ng). The alignment of MinD sequences from various bacteria showed that the proteins are highly conserved and share several regions of identity, including a conserved ATP-binding cassette. The overexpression of MinD(Ng) in wild-type Escherichia coli led to cell filamentation, while overexpression in an E. coli minD mutant restored a wild-type morphology to the majority of cells; therefore, gonococcal MinD is functional across species. Yeast two-hybrid studies and gel-filtration and sedimentation equilibrium analyses of purified His-tagged MinD(Ng) revealed a novel MinD(Ng) self-interaction. We have also shown by yeast two-hybrid analysis that MinD from E. coli interacts with itself and with MinD(Ng). These results indicate that MinD(Ng) is required for maintaining proper cell division and growth in N. gonorrhoeae and suggests that the self-interaction of MinD may be important for cell division site selection across species.

Pyrene excimer fluorescence: a spatially sensitive probe to monitor lipid-induced helical rearrangement of apolipophorin III.

Manduca sexta apolipophorin III (apoLp-III), an 18-kDa, monomeric, insect hemolymph apolipoprotein, is comprised of five amphipathic alpha-helices arranged as a globular bundle in the lipid-free state. Upon lipid binding, it is postulated that the bundle opens, exposing a continuous hydrophobic surface which becomes available for lipid interaction. To investigate lipid binding-induced helical rearrangements, we exploited the unique fluorescence characteristics of N-(1-pyrene)maleimide. Pyrene is a spatially sensitive extrinsic fluorescent probe, which forms excited-state dimers (excimers) upon close encounter with another pyrene molecule. Cysteine residues were introduced into apoLp-III (which otherwise lacks cysteine) at Asn 40 (helix 2) and/or Leu 90 (helix 3), creating two single-cysteine mutants (N40C-apoLp-III and L90C-apoLp-III) and N40C/L90C-apoLp-III, a double-cysteine mutant, which were labeled with pyrene maleimide. Pyrene-labeled N40C/L90C-apoLp-III, but not the pyrene-labeled single-cysteine mutants, exhibited strong excimer fluorescence in the lipid-free, monomeric state. Guanidine hydrochloride titration and temperature studies revealed a loss in excimer fluorescence, accompanied by a loss in the molar ellipticity of the protein. When apoLp-III interacts with phospholipid vesicles to form disklike complexes, a significant loss in excimer fluorescence was noted, indicating that the helices bearing the pyrene moieties diverge from each other. Pyrene excimer fluorescence was further employed to examine the relative orientation of lipid-bound apoLp-III molecules. Pyrene-labeled N40C- or L90C-apoLp-III displayed no excimer fluorescence in the disk complexes, while complexes prepared with an equal mixture of both single-labeled mutants did emit excimer fluorescence, indicating apoLp-III adopts a preferred nonrandom orientation around the perimeter of the bilayer disk. These studies establish pyrene excimer fluorescence as a useful spectroscopic tool to address intra- and intermolecular interactions of exchangeable apolipoproteins upon binding to lipid.

Folding and structural characterization of highly disulfide-bonded beetle antifreeze protein produced in bacteria.

The hyperactive antifreeze protein from the beetle, Tenebrio molitor, is an 8.5-kDa, threonine-rich protein containing 16 Cys residues, all of which are involved in disulfide bonds. When produced by Escherichia coli, the protein accumulated in the supernatant in an inactive, unfolded state. Its correct folding required days or weeks of oxidation at 22 or 4 degrees C, respectively, and its purification included the removal of imperfectly folded forms by reversed-phase HPLC. NMR spectroscopy was used to assess the degree of folding of each preparation. One-dimensional (1)H and two-dimensional (1)H total correlation spectroscopy spectra were particularly helpful in establishing the characteristics of the fully folded antifreeze in comparison to less well-folded forms. The recombinant antifreeze had no free -SH groups and was rapidly and completely inactivated by 10 mM DTT. It had a thermal hysteresis activity of 2.5 degrees C at a concentration of 1 mg/ml, whereas fish antifreeze proteins typically show a thermal hysteresis of approximately 1.0 degrees C at 10-20 mg/ml. The circular dichroism spectra of the beetle antifreeze had a superficial resemblance to those of alpha-helical proteins, but deconvolution of the spectra indicated the absence of alpha-helix and the presence of beta-structure and coil. NMR analysis and secondary structure predictions agree with the CD data and are consistent with a beta-helix model proposed for the antifreeze on the basis of its 12-amino-acid repeating structure and presumptive disulfide bond arrangement.

A molecular trigger of lipid binding-induced opening of a helix bundle exchangeable apolipoprotein.

Apolipophorin III (apoLp-III) from the sphinx moth, Manduca sexta, is a helix bundle protein that interacts reversibly with lipoproteins. Its five elongated amphipathic alpha-helices are organized in an antiparallel fashion, with helices 3 and 4 connected by a short 6-residue (PDVEKE) linker helix, termed helix 3'. Upon interaction with lipoproteins, apoLp-III opens to expose a continuous hydrophobic interior. It was postulated that helix bundle opening is preceded by an initiation step wherein helix 3' serves to recognize available lipoprotein surface binding sites. To test this hypothesis, helix 3' was replaced by residues that have a propensity to form a type I beta-turn, NPNG. This mutant apoLp-III was defective in lipoprotein binding assays. To define a more precise mode of interaction, the relevance of the presence of the hydrophobic Val-97 flanked by Asp-96 and Glu-98 was investigated by site-directed mutagenesis. V97N and D96N/V97N/E98Q apoLp-III were unable to compete with wild-type apoLp-III to initiate an interaction with lipoproteins, whereas D96N/E98Q apoLp-III was as competent as wild-type apoLp-III. The results suggest that Val-97 is critical, whereas Asp-96 and Glu-98 are irrelevant for initiating binding to lipoproteins. A model of binding is presented wherein apoLp-III is oriented with the helix 3' end of the molecule juxtaposed to the lipoprotein surface. Recognition of lipoprotein surface hydrophobic defects by Val-97 triggers opening of the helix bundle and facilitates formation of a stable binding interaction.

Orientation, positional, additivity, and oligomerization-state effects of interhelical ion pairs in alpha-helical coiled-coils.

The role of interhelical g-e' ion pairs in the dimerization specificity and stability of alpha-helical coiled-coils is highly controversial. Synthetic 35-residue coiled-coils based on the heptad repeat QgVaGbAcLdQeK f were used to investigate the effect of orientation of interhelical ion pairs between lysine and glutamic acid residues on coiled-coil stability. Stability was estimated from urea denaturation at 20 degreesC, monitoring unfolding with circular-dichroism spectroscopy. Double mutant cycles were employed to estimate the net interaction energy, Delta DeltaGuint, for the two orientations of the ion pair; Ee-Kg and Ke-Eg. Delta DeltaGuint was found to be about 1.4-fold higher for the Ee-Kg orientation in a coiled-coil containing an N-terminal disulfide bridge. The Delta DeltaGuint value was similar whether obtained from the middle heptad or averaged over all five heptads of the coiled-coil, suggesting that ion pairs contribute additively to coiled-coil stability. The effect of uncompensated charges was also illustrated by single substitutions of Gln with either Lys or Glu, resulting in Lys-Gln or Glu-Gln g-e' pairs. These substitutions were found to be twice as destabilizing at position g as at position e, and Lys was about twice as destabilizing as Glu at both positions e and g. In the absence of an interhelical disulfide bridge, Glu and Lys substitutions in the middle heptad were equally destabilizing at positions e and g (Lys continued to be more destabilizing than Glu) and the Delta DeltaGuint value for Lys-Glu ion pairs was not orientation dependent. These and previous results suggest the non-covalently-linked synthetic coiled-coils behave as molten globules, whereas a disulfide-bridge may "lock in" the structural differences between positions of the heptad repeat. Interhelical Lys-Glu ion pairs in either orientation promoted the formation of trimeric coiled-coils (in the absence of a disulfide bridge) while Gln-Gln g-e' interactions led to dimer formation. The results support a role for g-e' ionic attractions in controlling coiled-coil specificity, stability and oligomerization state, possibly through effects on the side-chain packing at the subunit interface.

Insights into the mechanism of heterodimerization from the 1H-NMR solution structure of the c-Myc-Max heterodimeric leucine zipper.

The oncoprotein c-Myc (a member of the helix-loop-helix-leucine zipper (b-HLH-LZ) family of transcription factors) must heterodimerize with the b-HLH-LZ Max protein to bind DNA and activate transcription. It has been shown that the LZ domains of the c-Myc and Max proteins specifically form a heterodimeric LZ at 20 degreesC and neutral pH. This suggests that the LZ domains of the c-Myc and Max proteins are playing an important role in the heterodimerization of the corresponding gene products in vivo. Initially, to gain an insight into the energetics of heterodimerization, we studied the stability of N-terminal disulfide-linked versions of the c-Myc and Max homodimeric LZs and c-Myc-Max heterodimeric LZ by fitting the temperature-induced denaturation curves monitored by circular dichroism spectroscopy. The c-Myc LZ does not homodimerize (as previously reported) and the c-Myc-Max heterodimeric LZ is more stable than the Max homodimeric LZ at 20 degreesC and pH 7.0. In order to determine the critical interhelical interactions responsible for the molecular recognition between the c-Myc and Max LZs, the solution structure of the disulfide-linked c-Myc-Max heterodimeric LZ was solved by two-dimensional 1H-NMR techniques at 25 degreesC and pH 4.7. Both LZs are alpha-helical and the tertiary structure depicts the typical left-handed super-helical twist of a two-stranded parallel alpha-helical coiled-coil. A buried salt bridge involving a histidine on the Max LZ and two glutamate residues on the c-Myc LZ is observed at the interface of the heterodimeric LZ. A buried H-bond between an asparagine side-chain and a backbone carbonyl is also observed. Moreover, evidence for e-g interhelical salt bridges is reported. These specific interactions give insights into the preferential heterodimerization process of the two LZs. The low stabilities of the Max homodimeric LZ and the c-Myc-Max heterodimeric LZ as well as the specific interactions observed are discussed with regard to regulation of transcription in this family of transcription factors.

Effects of lanthanide binding on the stability of de novo designed alpha-helical coiled-coils.

Effects of La3+ ion binding on the stability of de novo designed two-stranded alpha-helical coiled-coils were studied. The coiled-coils were composed of two 35-residue polypeptide chains based on the "native" heptad sequence Q(g)V(a)G(b)A(c)L(d)Q(e)K(f) and each contained a Cys residue at position 2a to allow formation of an interchain disulfide bridge. The effect of LaCl3 on the stability of five analogs containing two or three Glu substitutions per chain at heptad positions e and g was observed by urea denaturation at 20 degrees C. The analog E2(15,20), in which Glu residues are involved in interhelical i to i' + 5 repulsions, was stabilized relative to the control native peptide by addition of 50 mM LaCl3 to the buffer, whereas two analogs, in which Glu residues do not interact, were destabilized. These results suggest that LaCl3 may preferentially stabilize the folded state of E2(15,20) by the "bridging" of La3+ ions between two pairs of Glu residues usually involved in interhelical repulsions. Two analogs designed to contain two La3+ binding sites composed of three Glu residues each show greater stabilization by LaCl3 than E2(15,20) in the disulfide-bridged form. The apparent stabilization of E2(15,20) by La3+ binding was not observed with either Ca2+ or Mg2+, indicating that the effect is specific for trivalent versus divalent cations.

Fluorescence studies of exchangeable apolipoprotein-lipid interactions. Superficial association of apolipophorin III with lipoprotein surfaces.

Apolipophorin III (apoLp-III) from the Sphinx moth, Manduca sexta, is an 18-kDa exchangeable apolipoprotein that reversibly associates with lipoprotein particles. In the absence of lipid, apoLp-III exists as an elongated bundle of five amphipathic alpha-helices. Upon lipid association, the protein is postulated to undergo a major conformational change, wherein the bundle opens around hinge loop regions, resulting in exposure of its hydrophobic interior. Fluorescence quenching techniques have been employed to study apoLp-III helix topography and spatial arrangement in phospholipid disc complexes and intact lipoprotein particles. Intrinsic fluorescence of the single tyrosine in apoLp-III was exploited to monitor the location of helix 5 in model disc complexes. To investigate other regions of the protein, site-directed mutagenesis was performed to introduce cysteine residues, replacing Asn-40 (helix 2, N40C) or Leu-90 (helix 3, L90C), thereby providing two mutant apoLp-IIIs, each with a single site for covalent attachment of the extrinsic fluorescent probe, N-(1-pyrene) maleimide. In the lipid-free state, pyrene-N40C- and pyrene-L90C-apoLp-III were highly accessible to the negatively charged aqueous quencher KI, yielding Ksv values of 27.1 and 19.8 M-1, respectively. Upon binding to the surface of a spherical lipoprotein particle, Ksv values for KI decreased by about 90% for both pyrene-labeled apoLp-IIIs, indicating a significant change in the local microenvironment of the fluorophores. A lesser decrease in Ksv was observed when the pyrene-labeled apoLp-IIIs were bound to phospholipid disc complexes. When spin-labeled fatty acids 5-doxylstearic acid and 12-doxylstearic acid were used as lipophilic quenchers, tyrosine and pyrene fluorescence were more effectively quenched by 5-doxylstearic acid in both phospholipid bilayer disc complexes and spherical lipoprotein particles. These data provide insight into the spatial topography of apoLp-III alpha-helices in phospholipid disc complexes and support the concept that interaction with spherical lipoprotein particles results in superficial contact of apoL-III helical segments with the monolayer surface, providing a basis for its reversible binding ability.

Disulfide bond mapping and structural characterization of spruce budworm antifreeze protein.

The 9-kDa, Thr-, Ser-, and Cys-rich thermal hysteresis protein from spruce budworm (sbwTHP) is 10-30 times more effective than fish antifreeze proteins (AFPs) at depressing solution freezing points via ice-crystal growth inhibition. Since this insect protein is only available in microgram quantities from its natural source, recombinant sbwTHP was produced from inclusion bodies in Escherichia coli by a refolding protocol. Incompletely folded forms were removed during ion-exchange and reverse-phase chromatography, resulting in fully active sbwTHP that was indistinguishable in its properties from native sbwTHP. The antifreeze was completely inactivated by reduction, showed no reaction with sulfhydryl reagents, and was not inhibited by EDTA. All eight cysteine residues appear to be involved in disulfide bond formation. Tryptic cleavage and peptide analysis is consistent with linkages between the first and second cysteine residues, the third and fourth, fifth and eighth, and the sixth and seventh. NMR analysis confirmed that the fully folded form of sbwTHP was well structured and had a single conformation. Both NMR and CD spectra indicate the presence of extensive beta structure (70-80%) with little or no alpha helix. The protein maintains antifreeze activity over a broad range of pH values, and its conformation is independent of both temperature (over the range 0 degrees C to 20 degrees C), and the presence of 50% trifluoroethanol.

Positional dependence of the effects of negatively charged Glu side chains on the stability of two-stranded alpha-helical coiled-coils.

The effects on protein stability of negatively charged Glu side chains at different positions along the length of the alpha-helix were investigated in the two-stranded alpha-helical coiled-coil. A native coiled-coil has been designed which consists of two identical 35 residue polypeptide chains with a heptad repeat QgVaGbAcLdQeKf and a Cys residue at position 2 to allow the formation of an interchain 2-2' disulphide bridge. This coiled-coil contains no intra- or interchain electrostatic interactions and served as a control for peptides in which Glu was substituted for Gln in the e or g heptad positions. The effect of the substitutions on stability was determined by urea denaturation at 20 degrees C with the degree of unfolding monitored by circular dichroism spectroscopy. A Glu substituted for Gln near the N-terminus in each chain of the coiled-coil stabilizes the coiled-coil at pH 7, consistent with the charge-helix dipole interaction model. This stability increase is modulated by pH change and the addition of salt (KCl or guanidine hydrochloride), confirming the electrostatic nature of the effect. In contrast, Glu substitution in the middle of the helix destabilizes the coiled-coil because of the lower helical propensity and hydrophobicity of Glu compared with Gln at pH7. Taking the intrinsic differences into account, the apparent charge-helix dipole interaction at the N-terminus is approximately 0.35 kcal/mol per Glu substitution. A Glu substitution at the C-terminus destabilizes the coiled-coil more than in the middle owing to the combined effects of intrinsic destabilization and unfavourable charge-helix dipole interaction with the negative pole of the helix dipole. The estimated destabilizing charge-helix dipole interaction of 0.08 kcal/mol is smaller than the stabilizing interaction at the N-terminus. The presence of a 2-2'disulphide bridge appears to have little influence on the magnitude of the charge-helix dipole interactions at either end of the coiled-coil.

Salt effects on protein stability: two-stranded alpha-helical coiled-coils containing inter- or intrahelical ion pairs.

An investigation into the role of surface-accessible ion pairs in protein stability was carried out by determining the effects of added salt (KCl, MgCl2 and LaCl3) at neutral and acidic pH on the stability of de novo designed two-stranded alpha-helical coiled-coils. The effects of salt on the stability of coiled-coils containing interhelical i to i' + 5 or intrahelical i to i + 4 and i to i + 3 Lys-Glu ion pairs were compared to the effects on the stability of a control coiled-coil, which contained no intra- or interhelical ion pair. These studies indicate that ionic interactions contribute to coiled-coil stability. The results show that added salt can have complex effects on protein stability, involving stabilizing and destabilizing contributions with the net effect depending on the nature of the charged residues and ionic interactions present in the protein.

Neutrophil-activating peptide-2 and melanoma growth-stimulatory activity are functional as monomers for neutrophil activation.

Neutrophil-activating peptide-2 (NAP-2) and melanoma growth-stimulatory activity (MGSA) are members of the chemokine family of inflammatory proteins. The structures of NAP-2, determined by x-ray crystallography, and MGSA, elucidated by NMR spectroscopy, revealed a tetramer and dimer, respectively. In order to address the relevance of multimeric species to their activities on neutrophils, analogs of NAP-2 and MGSA were synthesized in which the backbone amide proton of Leu-22 in NAP-2, and Val-26 in MGSA, was substituted with the bulky methyl group (NH --> NCH3). These analogs were shown to be monomeric by sedimentation equilibrium ultracentrifugation studies and were similar to the corresponding native protein in assays for neutrophil elastase release and Ca2+ mobilization from IL-8R1 and IL-8R2 transformed cells. Sedimentation equilibrium studies of the native NAP-2 and MGSA were also carried out to address the association behavior. For NAP-2, there was no evidence for the tetramer, but an equilibrium between monomers and dimers and the dissociation constant was calculated to be 50-100 microM. Similarly, MGSA showed a monomer-dimer equilibrium with a Kd of approximately 5 microM. The data from the monomeric analogs and also the calculation of dissociation constants indicate that NAP-2 and MGSA have a tendency to associate above the concentrations required for maximal activity or for receptor activation, but at functional concentrations they are predominantly monomers.

Fluorescence studies of lipid association-induced conformational adaptations of an exchangeable amphipathic apolipoprotein.

The conformational adaptability of Manduca sexta apolipophorin III (apoLp-III) has been evaluated by monitoring the spectroscopic properties of its sole tyrosine residue, Tyr145, present in the fifth helical segment of the protein. M. sexta apoLp-III adopts a globular five-helix bundle structure in solution and has been postulated to undergo an opening at putative hinge domains upon interaction with lipid surfaces. Previous results have shown that the intrinsic fluorescence of Tyr145 is highly quenched in the closed, water-soluble conformation but is dramatically enhanced upon lipid association. We have carried out a spectroscopic characterization of Tyr145 and its microenvironment, to enable its use as a structural probe of lipid-induced conformational changes of apoLp-III. The pKa of Tyr145 in lipid-free apoLp-III was found to be 10.5, as determined from uv-spectrophotometry, indicating that, in the ground state, the tyrosyl phenolic group is not ionized under physiological conditions. Compared to free tyrosine in aqueous buffer (pH 7.0), a red shift (77 nm) in the (lambda)max of absorbance of Tyr145 was observed, suggesting that an H-bonding interaction is responsible for the quenched state of tyrosine fluorescence. In an effort to explain the observed quenching phenomenon, the quantum yield and lifetimes of Tyr145 fluorescence emission were investigated as a function of pH and lipid binding. The quantum yield of Tyr145 in lipid-free apoLp-III was enhanced fivefold upon decreasing the pH, with a half-maximal point around pH 5.5. Time-resolved fluorescence decay analysis showed that Tyr145 exhibits nonexponential emission decay with two components having lifetimes of 3.3 ns (76%) and 0.89 ns (24%) in the lipid-free state. The lifetime and amplitude of Tyr145 remain essentially unaltered upon lipid association or decreasing the pH. This is consistent with the hypothesis that, in the lipid-free helix bundle conformation, a quenching residue exists within H-bonding distance of the phenolic side chain of Tyr145 which, at physiological pH, is responsible for the observed fluorescence quenching. Opening of the helix bundle repositions this acceptor base, possibly a carboxylate or an imidazole side chain, making it unavailable for quenching. Using differential polarized phase and modulation fluorometry, it was seen that the segmental motion of Tyr145 is also altered considerably upon lipid interaction. These spectroscopic and motional properties of Tyr145 distinguish this unique residue as a useful probe to monitor structural flexibility of apoLp-III.

Disulfide bond engineering to monitor conformational opening of apolipophorin III during lipid binding.

Apolipophorin III (apoLp-III) from the Sphinx moth, Manduca sexta, is an exchangeable, amphipathic apolipoprotein that alternately exists in water-soluble and lipid-bound forms. It is organized as a five-helix bundle in solution, which has been postulated to open at putative hinge domains to expose the hydrophobic interior, thereby facilitating interaction with the lipoprotein surface (Breiter, D. R. , Kanost, M. R., Benning, M. M., Wesenberg, G., Law, J. H., Wells, M. A., Rayment, I., and Holden, H. M. (1991) Biochemistry 30, 603-608). To test this hypothesis, we engineered two cysteine residues in apoLp-III, which otherwise lacks cysteine, by site-directed mutagenesis at Asn-40 and Leu-90. Under oxidizing conditions the two cysteines spontaneously form a disulfide bond, which should tether the helix bundle and thereby prevent opening and concomitant lipid interaction. N40C/L90C apoLp-III was overexpressed in Escherichia coli and characterized for disulfide bond formation, secondary structure content, and stability, under both oxidizing and reducing conditions. Functional characterization was carried out by comparing the abilities of the oxidized and reduced protein to associate with modified lipoproteins in vitro. While the reduced form behaved like wild type apoLp-III, the oxidized form was unable to associate with lipoproteins. These results suggest that opening of the helix bundle is required for interaction with lipoproteins and provide a molecular basis for the dual existence of water-soluble and lipid-bound forms of apoLp-III. However, in phospholipid bilayer association assays, wild type, reduced, and oxidized N40C/L90C apoLp-III exhibited similar abilities to transform dimyristoylphosphatidylcholine multilamellar vesicles to disc-like complexes, as judged by electron microscopy. These data emphasize that underlying differences exist in initiating or maintaining a stable interaction of apoLp-III with phospholipid disc complexes versus spherical lipoprotein surfaces.

Kinetic study on the formation of a de novo designed heterodimeric coiled-coil: use of surface plasmon resonance to monitor the association and dissociation of polypeptide chains.

The surface plasmon resonance (SPR) technique was used to study the formation kinetics of a de novo designed coiled-coil (E/K coil). The E/K coil is made up of two distinct peptides (E and K) each with five heptad (g-a-b-c-d-e-f) repeats. The E peptide's heptad sequence is E-V-S-A-L-E-K, and the K peptide's heptad sequence is K-V-S-A-L-K-E. A linker C-nL-G-G-G (nL = norleucine) is present at the C-terminus of the E peptide and at the N-terminus of the K peptide for the SPR studies. Heterodimer formation involves both electrostatic and hydrophobic interactions at the dimer interface. Under conditions that favor the heterodimer formation, the CD signal ([theta]222) varied as a function of peptide concentration. The estimated dissociation constant (Kd) was 2.45 +/- 0.71 nM. Denaturation studies with guanidine-HCI (GdnHC11/2 = 3.9 M) suggested a value of 3.53 +/- 0.48 nM. For the SPR investigation, the peptides were biotinylated and linked to streptavidin in order to increase their effective molecular weight and consequently enhance the signal intensity. Biotinylation in itself did not impede coiled-coil formation based on CD measurements. The biosensor study revealed a slow dissociation rate constant for the heterodimer (kd approximately 2 x 10(-4) s-1) and a moderately fast association rate constant [ka approximately (4.27-4.53) x 10(5) M-1 s-1). This gives a calculated Kd of 0.47-0.50 nM, which agrees reasonably well with the equilibrium CD studies. Therefore, based on the SPR data, the preference for heterodimer formation is due to a combination of moderately fast association and slow dissociation rates.

1H, 15N and 13C resonance assignments and monomeric structure of the amino-terminal extracellular domain of epithelial cadherin.

E-cadherin is a transmembrane protein that provides Ca(2+)-dependent cell adhesion to epithelial cells. The large majority of the 1H, 15N, 13C and 13CO resonances of a 146-amino acid polypeptide from epithelial (E-) cadherin have been assigned using multidimensional NMR spectroscopy. The structure of the amino-terminal 100 amino acids, corresponding to the first extracellular repeat of E-cadherin [Overduin et al. (1995) Science, 267, 386-389], has been refined. The monomeric state of this isolated domain is demonstrated by light scattering and sedimentation analysis. Seven beta-strands and two short helices were identified by patterns of NOE cross-peaks, vicinal coupling constants and chemical shift indices. A novel structural motif termed a quasi-beta-helix found in the crystal structure of a neural (N-) cadherin domain [Shapiro et al. (1995) Nature, 374, 327-337] is characterized in detail for the first time by NMR. Slowly exchanging amides were concentrated in the beta-sheet region and quasi-beta-helix. The beta-barrel fold of the cadherin domain is topologically similar to the immunoglobulin fold. Comparison of this solution structure to the crystallized dimers of the N-terminal pair of E-cadherin domains [Nagar et al. (1996) Nature, 380, 360-364] and of the homologous single domain of N-cadherin reveals a conserved cadherin fold with minor structural differences, which can be accounted for by differences in metal ligation and oligomeric state.

The relative positions of alanine residues in the hydrophobic core control the formation of two-stranded or four-stranded alpha-helical coiled-coils.

The objective of this study was to investigate the positional effect of hydrophobic interactions in the alpha-helical interface in controlling the formation of two-stranded and four-stranded coiled-coils. Two disulfide-bridged antiparallel coiled-coils were designed which differ only in the position of a single Ala residue in the middle heptad: in peptide 2H the Ala residues are in register (in the same rung), while in peptide 4H they are not. Data from size-exclusion chromatography and sedimentation equilibrium experiments showed that under benign conditions peptides 2H and 4H were two-stranded and four-stranded coiled-coils respectively. These results, in conjunction with molecular modeling studies, suggests that when four Ala residues are in the same plane of a potential four-stranded coiled-coil, the small side chains of Ala would create a large cavity in the hydrophobic interface of the potential four-stranded structure which is destabilizing and favors the two-stranded, disulfide-bridged coiled-coil. In contrast, an alternating Leu-Ala hydrophobic packing in the two planes distributes the potential cavity over a larger region, which may be partially filled by minor adjustments of the neighboring Leu side chains. As a result, there is still sufficient hydrophobic contact to maintain the four stranded structure.