Structural differences between hypoxanthine phosphoribosyltransferase family members highlight opportunities for antiparasitic drug design in neglected diseases

Approaches to identify novel druggable targets for treating neglected diseases include computational studies that predict possible interactions of drugs and their molecular targets. Hypoxanthine phosphoribosyltransferase (HPRT) plays a central role in the purine salvage pathway. This enzyme is essential for the survival of the protozoan parasite T. cruzi, the causal agent of Chagas disease, and other parasites related to neglected diseases. Here we found dissimilar functional behaviours between TcHPRT and the human homologue, HsHPRT, in the presence of substrate analogues that can lie in differences in their oligomeric assemblies and structural features. To shed light on this issue, we carried out a comparative structural analysis between both enzymes. Our results show that HsHPRT is considerably more resistant to controlled proteolysis than TcHPRT. Moreover, we observed a variation in the length of two key loops depending on the structural arrangement of each protein (groups D1T1 and D1T1'). Such variations might be involved in inter-subunit communication or influencing the oligomeric state. Besides, to understand the molecular basis that govern D1T1 and D1T1' folding groups, we explored the distribution of charges on the interaction surfaces of TcHPRT and HsHPRT, respectively. To know whether the rigidity degree bears effect on the active site, we studied the flexibility of both proteins. The analysis performed here illuminates the underlying reasons and significance behind each protein's preference for one or the other quaternary arrangement that can be exploited for therapeutic approaches.

Zoledronate repositioning as a potential trypanocidal drug. Trypanosoma cruzi HPRT an alternative target to be considered

Chagas disease is caused by the protozoan parasite Trypanosoma cruzi and affects 7 million people worldwide. Considering the side effects and drug resistance shown by current treatments, the development of new anti-Chagas therapies is an urgent need. T. cruzi hypoxanthine phosphoribosyltransferase (TcHPRT), the key enzyme of the purine salvage pathway, is essential for the survival of trypanosomatids. Previously, we assessed the inhibitory effect of different bisphosphonates (BPs), HPRT substrate analogues, on the activity of the isolated enzyme. BPs are used as a treatment for bone diseases and growth inhibition studies on T. cruzi have associated BPs action with the farnesyl diphosphate synthase inhibition. Here, we demonstrated significant growth inhibition of epimastigotes in the presence of BPs and a strong correlation with our previous results on the isolated TcHPRT, suggesting this enzyme as a possible and important target for these drugs. We also found that the parasites exhibited a delay at S phase in the presence of zoledronate pointing out enzymes involved in the cell cycle, such as TcHPRT, as intracellular targets. Moreover, we validated that micromolar concentrations of zoledronate are capable to interfere with the progression of cell infection by this parasite. Altogether, our findings allow us to propose the repositioning of zoledronate as a promising candidate against Chagas disease and TcHPRT as a new target for future rational design of antiparasitic drugs.

Peptides Derived From the α-Core and γ-Core Regions of a Putative Silybum marianum Flower Defensin Show Antifungal Activity Against Fusarium graminearum

Fusarium graminearum is the etiological agent of Fusarium head blight (FHB), a disease that produces a significant decrease in wheat crop yield and it is further aggravated by the presence of mycotoxins in the affected grains that may cause health problems to humans and animals. Plant defensins and defensin-like proteins are antimicrobial peptides (AMPs); they are small basic, cysteine-rich peptides (CRPs) ubiquitously expressed in the plant kingdom and mostly involved in host defence. They present a highly variable sequence but a conserved structure. The γ-core located in the C-terminal region of plant defensins has a conserved β-hairpin structure and is a well-known determinant of the antimicrobial activity among disulphide-containing AMPs. Another conserved motif of plant defensins is the α-core located in the N-terminal region, not conserved among the disulphide-containing AMPs, it has not been yet extensively studied. In this report, we have cloned the putative antimicrobial protein DefSm2, expressed in flowers of the wild plant Silybum marianum. The cDNA encodes a protein with two fused basic domains of an N-terminal defensin domain (DefSm2-D) and a C-terminal Arg-rich and Lys-rich domain. To further characterize the DefSm2-D domain, we built a 3D template-based model that will serve to support the design of novel antifungal peptides. We have designed four potential antifungal peptides: two from the DefSm2-D α-core region (SmAP_α1-21 and SmAP_α10-21) and two from the γ-core region (SmAP_γ27-44 and SmAP_γ29-35). We have chemically synthesized and purified the peptides and further characterized them by electrospray ionization mass spectrometry (ESI-MS) and Circular dichroism (CD) spectroscopy. SmAP_α1-21, SmAP_α10-21, and SmAP_γ27-44 inhibited the growth of the phytopathogen F. graminearum at low micromolar concentrations. Conidia exposure to the fungicidal concentration of the peptides caused membrane permeabilization to the fluorescent probe propidium iodide (PI), suggesting that this is one of the main contributing factors in fungal cell killing. Furthermore, conidia treated for 0.5h showed cytoplasmic disorganization as observed by transmission electron microscopy (TEM). Remarkably, the peptides derived from the α-core induced morphological changes on the conidia cell wall, which is a promising target since its distinctive biochemical and structural organization is absent in plant and mammalian cells.

A metabolic control analysis approach to introduce the study of systems in biochemistry: the glycolytic pathway in the red blood cell

Metabolic control analysis (MCA) is a promising approach in biochemistry aimed at understanding processes in a quantitative fashion. Here the contribution of enzymes and transporters to the control of a given pathway flux and metabolite concentrations is determined and expressed quantitatively by means of numerical coefficients. Metabolic flux can be influenced by a wide variety of modulators acting on one or more metabolic steps along the pathway. We describe a laboratory exercise to study metabolic regulation of human erythrocytes (RBCs). Within the framework of MCA, students use these cells to determine the sensitivity of the glycolytic flux to two inhibitors (iodoacetic acid: IA, and iodoacetamide: IAA) known to act on the enzyme glyceraldehyde-3-phosphate-dehydrogenase. Glycolytic flux was estimated by determining the concentration of extracellular lactate, the end product of RBC glycolysis. A low-cost colorimetric assay was implemented, that takes advantage of the straightforward quantification of the absorbance signal from the photographic image of the multi-well plate taken with a standard digital camera. Students estimate flux response coefficients for each inhibitor by fitting an empirical function to the experimental data, followed by analytical derivation of this function. IA and IAA exhibit qualitatively different patterns, which are thoroughly analyzed in terms of the physicochemical properties influencing their action on the target enzyme. IA causes highest glycolytic flux inhibition at lower concentration than IAA. This work illustrates the feasibility of using the MCA approach to study key variables of a simple metabolic system, in the context of an upper level biochemistry course. © 2018 International Union of Biochemistry and Molecular Biology, 46(5):502-515, 2018.

Amyloidogenic propensity of a natural variant of human apolipoprotein A-I: stability and interaction with ligands

A number of naturally occurring mutations of human apolipoprotein A-I (apoA-I) have been associated with hereditary amyloidoses. The molecular mechanisms involved in amyloid-associated pathology remain largely unknown. Here we examined the effects of the Arg173Pro point mutation in apoA-I on the structure, stability, and aggregation propensity, as well as on the ability to bind to putative ligands. Our results indicate that the mutation induces a drastic loss of stability, and a lower efficiency to bind to phospholipid vesicles at physiological pH, which could determine the observed higher tendency to aggregate as pro-amyloidogenic complexes. Incubation under acidic conditions does not seem to induce significant desestabilization or aggregation tendency, neither does it contribute to the binding of the mutant to sodium dodecyl sulfate. While the binding to this detergent is higher for the mutant as compared to wt apoA-I, the interaction of the Arg173Pro variant with heparin depends on pH, being lower at pH 5.0 and higher than wt under physiological pH conditions. We suggest that binding to ligands as heparin or other glycosaminoglycans could be key events tuning the fine details of the interaction of apoA-I variants with the micro-environment, and probably eliciting the toxicity of these variants in hereditary amyloidoses.

Intervening in the β-barrel structure of lipid binding proteins: consequences on folding, ligand-binding and aggregation propensity

Natural β-folds manage to fold up successfully. By contrast, attempts to dissect fragments or peptides from well folded β-sheet proteins have met with insurmountable difficulties. Here we briefly review selected successful cases of intervention on the well-known scaffold of intestinal fatty acid binding protein (IFABP). Lessons from these examples might set guidelines along the design of proteins belonging to this class. Impact of modifications on topology, binding and aggregation is highlighted. With the aid of abridged variants of IFABP we focus on key structural features responsible for the assembly into oligomeric forms or aggregates.

A positive cooperativity binding model between Ly49 natural killer cell receptors and the viral immunoevasin m157: kinetic and thermodynamic studies

Natural killer (NK) cells discriminate between healthy and virally infected or transformed cells using diverse surface receptors that are both activating and inhibitory. Among them, the homodimeric Ly49 NK receptors, which can adopt two distinct conformations (backfolded and extended), are of particular importance for detecting cells infected with mouse cytomegalovirus (CMV) via recognition of the viral immunoevasin m157. The interaction of m157 with activating (Ly49H) and inhibitory (Ly49I) receptors governs the spread of mouse CMV. We carried out kinetic and thermodynamic experiments to elucidate the Ly49/m157 binding mechanism. Combining surface plasmon resonance, fluorescence anisotropy, and circular dichroism (CD), we determined that the best model to describe both the Ly49H/m157 and Ly49I/m157 interactions is a conformational selection mechanism where only the extended conformation of Ly49 (Ly49*) is able to bind the first m157 ligand followed by binding of the Ly49*/m157 complex to the second m157. The interaction is characterized by strong positive cooperativity such that the second m157 binds the Ly49 homodimer with a 1000-fold higher sequential constant than the first m157 (∼10(8) versus ∼10(5) M(-1)). Using far-UV CD, we obtained evidence for a conformational change in Ly49 upon binding m157 that could explain the positive cooperativity. The rate-limiting step of the overall mechanism is a conformational transition in Ly49 from its backfolded to extended form. The global thermodynamic parameters from the initial state (backfolded Ly49 and m157) to the final state (Ly49*/(m157)2) are characterized by an unfavorable enthalpy that is compensated by a favorable entropy, making the interaction spontaneous.

Truncation of a β-barrel scaffold dissociates intrinsic stability from its propensity to aggregation

Δ98Δ is a functional all-β sheet variant of intestinal fatty acid binding protein (IFABP) that was generated by controlled proteolysis. This framework is useful to study the molecular determinants related to aggregation of β-barrel proteins. Albeit displaying increased conformational plasticity, Δ98Δ exhibits a nativelike β-barrel topology and is able to support a cooperative folding behavior. Here we present a comparative study of IFABP and Δ98Δ regarding their conformational perturbation and aggregation propensity triggered by trifluoroethanol. Both proteins share a common nucleation-elongation mechanism, whereby the rate-limiting step is the formation of stable dimeric nuclei followed by the association of monomers to the growing aggregates. Despite leading to a less stable structure, the extensive truncation of IFABP yields a form exhibiting a somewhat lower tendency to aggregate. This finding appears at odds with the established notion that a perturbation of the native compact fold should necessarily favor the population of aggregation-prone species. In addition to the aggregation propensity dictated by a given amino-acid sequence, our contention holds that long-range interactions might also play a major role in determining the overall aggregation propensity.

Probing protein surface with a solvent mimetic carbene coupled to detection by mass spectrometry

Much knowledge into protein folding, ligand binding, and complex formation can be derived from the examination of the nature and size of the accessible surface area (SASA) of the polypeptide chain, a key parameter in protein science not directly measurable in an experimental fashion. To this end, an ideal chemical approach should aim at exerting solvent mimicry and achieving minimal selectivity to probe the protein surface regardless of its chemical nature. The choice of the photoreagent diazirine to fulfill these goals arises from its size comparable to water and from being a convenient source of the extremely reactive methylene carbene (:CH(2)). The ensuing methylation depends primarily on the solvent accessibility of the polypeptide chain, turning it into a valuable signal to address experimentally the measurement of SASA in proteins. The superb sensitivity and high resolution of modern mass spectrometry techniques allows us to derive a quantitative signal proportional to the extent of modification (EM) of the sample. Thus, diazirine labeling coupled to electrospray mass spectrometry (ESI-MS) detection can shed light on conformational features of the native as well as non-native states, not easily addressable by other methods. Enzymatic fragmentation of the polypeptide chain at the level of small peptides allows us to locate the covalent tag along the amino acid sequence, therefore enabling the construction of a map of solvent accessibility. Moreover, by subsequent MS/MS analysis of peptides, we demonstrate here the feasibility of attaining amino acid resolution in defining the target sites.

Thermal regulation of membrane lipid fluidity by a two-component system in Bacillus subtilis

This article describes a simple and robust laboratory exercise on the regulation of membrane unsaturated fatty acid composition in bacteria by a decrease in growth temperature. We take advantage of the well characterized Des pathway of Bacillus subtilis, composed of a Δ5-desaturase (encoded by the des gene) and the canonical two-component system DesK-DesR, to study the transcriptional regulation of des during cold shock. Students analyze the expression of a reporter transcriptional fusion between the des promoter and the bacterial lacZ gene in a wild-type B. subtilis strain and in des or desK-desR mutants grown under different culture conditions. Measurements of β-galactosidase activity allow them to investigate how the Des pathway works and to assess the role of each component of this regulatory system.

Gain of local structure in an amphipathic peptide does not require a specific tertiary framework

In this work, we studied how an amphipathic peptide of the surface of the globular protein thioredoxin, TRX94-108, acquires a native-like structure when it becomes involved in an apolar interaction network. We designed peptide variants where the tendency to form alpha-helical conformation is modulated by replacing each of the leucine amino acid residues by an alanine. The induction of structure caused by sodium dodecyl sulfate (SDS) binding was studied by capillary zone electrophoresis, circular dichroism, DOSY-NMR, and molecular dynamics simulations (MDS). In addition, we analyzed the strength of the interaction between a C18 RP-HPLC matrix and the peptides. The results presented here reveal that (a) critical elements in the sequence of the wild-type peptide stabilize a SDS/peptide supramolecular cluster; (b) the hydrophobic nature of the interaction between SDS molecules and the peptide constrains the ensemble of conformations; (c) nonspecific apolar surfaces are sufficient to stabilize peptide secondary structure. Remarkably, MDS shed light on a contact network formed by a limited number of SDS molecules that serves as a structural scaffold preserving the helical conformation of this module. This mechanism might prevail when a peptide with low helical propensity is involved in structure consolidation. We suggest that folding of peptides sharing this feature does not require a preformed tightly-packed protein core. Thus, the formation of specific tertiary interactions would be the consequence of peptide folding and not its cause. In this scenario, folding might be thought of as a process that includes unspecific rounds of structure stabilization guiding the protein to the native state.

The structure of calreticulin C-terminal domain is modulated by physiological variations of calcium concentration

Calreticulin is an abundant endoplasmic reticulum resident protein that fulfills at least two basic functions. Firstly, due to its ability to bind monoglucosylated high mannose oligosaccharides, calreticulin is a central component of the folding quality control system of glycoproteins. On the other hand, thanks to its capacity to bind high amounts of calcium, calreticulin is one of the main calcium buffers in the endoplasmic reticulum. This last activity resides on a highly negatively charged domain located at the C terminus. Interestingly, this domain has been proposed to regulate the intracellular localization of calreticulin. Structural information for this domain is currently scarce. Here we address this issue by employing a combination of biophysical techniques and molecular dynamics simulation. We found that calreticulin C-terminal domain at low calcium concentration displays a disordered structure, whereas calcium addition induces a more rigid and compact conformation. Remarkably, this change develops when calcium concentration varies within a range similar to that taking place in the endoplasmic reticulum upon physiological fluctuations. In addition, a much higher calcium concentration is necessary to attain similar responses in a peptide displaying a randomized sequence of calreticulin C-terminal domain, illustrating the sequence specificity of this effect. Molecular dynamics simulation reveals that this ordering effect is a consequence of the ability of calcium to bring into close proximity residues that lie apart in the primary structure. These results place calreticulin in a new setting in which the protein behaves not only as a calcium-binding protein but as a finely tuned calcium sensor.

Structural selection of a native fold by peptide recognition. Insights into the thioredoxin folding mechanism

Thioredoxins (TRXs) are monomeric alpha/beta proteins with a fold characterized by a central twisted beta-sheet surrounded by alpha-helical elements. The interaction of the C-terminal alpha-helix 5 of TRX against the remainder of the protein involves a close packing of hydrophobic surfaces, offering the opportunity of studying a fine-tuned molecular recognition phenomenon with long-range consequences on the acquisition of tertiary structure. In this work, we focus on the significance of interactions involving residues L94, L99, E101, F102, L103 and L107 on the formation of the noncovalent complex between reduced TRX1-93 and TRX94-108. The conformational status of the system was assessed experimentally by circular dichroism, intrinsic fluorescence emission and enzymic activity; and theoretically by molecular dynamics simulations (MDS). Alterations in tertiary structure of the complexes, resulting as a consequence of site specific mutation, were also examined. To distinguish the effect of alanine scanning mutagenesis on secondary structure stability, the intrinsic helix-forming ability of the mutant peptides was monitored experimentally by far-UV CD spectroscopy upon the addition of 2,2,2-trifluoroethanol, and also theoretically by Monte Carlo conformational search and MDS. This evidence suggests a key role of residues L99, F102 and L103 on the stabilization of the secondary structure of alpha-helix 5, and on the acquisition of tertiary structure upon complex formation. We hypothesize that the transition between a partially folded and a native-like conformation of reduced TRX1-93 would fundamentally depend on the consolidation of a cooperative tertiary unit based on the interaction between alpha-helix 3 and alpha-helix 5.

Consolidation of the Thioredoxin Fold by Peptide Recognition: Interaction between E. coli Thioredoxin Fragments 1−93 and 94−108

Escherichia coli thioredoxin (TRX) catalyzes redox reactions via the reversible oxidation of the conserved active center WCGPC. TRX is a monomeric alpha/beta protein with a fold characterized by a central beta-sheet surrounded by alpha-helical elements. The interaction of the C-terminal alpha-helix (helix 5) of TRX against the remainder of the protein involves the close packing of hydrophobic surfaces, opening the possibility of studying a fine-tuned molecular recognition phenomenon. To evaluate the relevance of this interaction on the folding mechanism of TRX, we characterize TRX1-93, a truncated variant of TRX devoid of the last stretch of 15 amino acid residues that includes helix 5. TRX1-93 may possibly represent a molecular form where the folding process becomes interrupted, giving rise to a structure exhibiting the features of a molten globule state. This was assessed by circular dichroism, intrinsic fluorescence, binding of the probe ANS, size-exclusion chromatography, limited proteolysis, and calorimetry. Remarkably, fragment TRX1-93 interacts with peptide TRX94-108 (KD approximately 2-12 microM), bringing forth the restoration of native-like signatures and enzymic function. This represents a molecular event of reciprocal structure selection where both partners gain order, thus leading to long-range consequences on conformation. In this context, the binding of the C-terminal helix could signify a late event in the consolidation of the overall TRX fold.

Exploring protein interfaces with a general photochemical reagent

Protein folding, natural conformational changes, or interaction between partners involved in recognition phenomena brings about differences in the solvent-accessible surface area (SASA) of the polypeptide chain. This primary event can be monitored by the differential chemical reactivity of functional groups along the protein sequence. Diazirine (DZN), a photoreactive gas similar in size to water, generates methylene carbene (:CH(2)). The extreme chemical reactivity of this species allows the almost instantaneous and indiscriminate modification of its immediate molecular cage. (3)H-DZN was successfully used in our laboratory for studying protein structure and folding. Here we address for the first time the usefulness of this probe to examine the area of interaction in protein-protein complexes. For this purpose we chose the complex formed between hen egg white lysozyme (HEWL) and the monoclonal antibody IgG(1) D1.3. :CH(2) labeling of free HEWL or complexed with IgG(1) D1.3 yields 2.76 and 2.32 mmol CH(2) per mole protein at 1 mM DZN concentration, respectively. This reduction (15%) becomes consistent with the expected decrement in the SASA of HEWL occurring upon complexation derived from crystallographic data (11%), in agreement with the known unspecific surface labeling reaction of :CH(2). Further comparative analysis at the level of tryptic peptides led to the identification of the sites involved in the interaction. Remarkably, those peptides implicated in the contact area show the highest differential labeling: H(15)GLDNYR(21), G(117)TDVQAWIR(125), andG(22)YSLGNWVCAAK(33). Thus, protein footprinting with DZN emerges as a feasible methodology useful for mapping contact regions of protein domains involved in macromolecular assemblies.

Delta98delta, a functional all-beta-sheet abridged form of intestinal fatty acid binding protein

Intestinal fatty acid binding protein (IFABP) is a 15 kDa intracellular lipid-binding protein exhibiting a beta-barrel fold that resembles a clamshell. The beta-barrel, which encloses the ligand binding cavity, consists of two perpendicular five-stranded beta-sheets with an intervening helix-turn-helix motif between strands A and B. Delta98delta (fragment 29-126 of IFABP) was obtained either in its recombinant form or by limited proteolysis with clostripain. Despite lacking extensive stretches involved in the closure of the beta-barrel, delta98delta remains soluble and stable in solution. Spectroscopic analyses by circular dichroism, ultraviolet absorption, and intrinsic fluorescence indicate that the fragment retains substantial beta-sheet content and tertiary interactions. In particular, the environment around W82 is identical in both delta98delta and IFABP, a fact consistent with the conservation in the former of all the critical amino acid residues belonging to the hydrophobic core. In addition, the Stokes radius of delta98delta is similar to that of IFABP and 16% larger than that calculated from its molecular weight (11 kDa). The monomeric status of delta98delta was further confirmed by chemical cross-linking experiments. Although lacking 25% of the amino acids of the parent protein, in the presence of GdnHCl, delta98delta unfolds through a cooperative transition showing a midpoint at 0.90 M. Remarkably, it also preserves binding activity for fatty acids (Kd = 5.1 microM for oleic acid and Kd = 0.72 microM for trans-parinaric acid), a fact that exerts a stabilizing effect on its structure. These cumulative evidences show that delta98delta adopts a monomeric state with a compact core and a loose periphery, being so far the smallest structure of its kind preserving binding function.

The purine transferase from Trypanosoma cruzi as a potential target for bisphosphonate-based chemotherapeutic compounds

We identified and tested bisphosphonates as inhibitors of a protozoan molecular target. Computational modeling studies demonstrated that these compounds are mimics of the natural substrate of the enzyme. The most potent bisphosphonates in vitro are pamidronate and risedronate, which inhibit the purine transferase from Trypanosoma cruzi in the micromolar range.

A subnanogram assay for phospholipase activity based on a long-chain radioiodinatable phosphatidylcholine

Here, we introduce a radioiodinatable long-chain phosphatidylcholine (BHC12PC) which serves as the base for a very sensitive phospholipase assay. This compound has a 4-hydroxyphenyl group attached at the end of the fatty acyl chain located in position sn-2. This feature enables this phospholipid to be radioiodinated. BHC12PC was tested as a substrate of Naja naja naja PLA(2) and Bacillus cereus PLC in a mixed micellar system with Triton X-100. The detection limit for the assays was 0.25ng of PLA(2) and 0.05ng of PLC, thus becoming one of the most sensitive methods described so far. A low specific radioactivity (500microCi/mmol) suffices to achieve this level of sensitivity. In both cases, the behavior of BHC12PC was indistinguishable from that shown by phospholipids with n-acyl chains of similar length. The choice of spacer prevents any unfavorable interaction of the bulky 4-hydroxyphenyl group at the active site of the enzymes. The progress of the reaction as monitored by thin-layer chromatography is compared side by side with an alternative method based on the selective adsorption of BHC12PC to silica gel, which renders identical results in a simpler fashion. An additional advantage of BHC12PC is that the cost per Ci of the radioiodinated derivative is significantly lower than that of other labeled phospholipids ((3)H, (14)C, or (32)P).

On how the conformation of biliverdins influences their reduction to bilirubins: a biological and molecular modeling study

The cyclic 2,18-bridged biliverdin (2) is excreted in rat bile without reduction to the corresponding bilirubin. Conformational analysis, employing an optimized Monte Carlo method and a mixed Monte Carlo/stochastic dynamics, reveals that biliverdin IXalpha (1) and the cyclic analogue 2 adopt 'lock washer' conformations, stabilized by the presence of intramolecular hydrogen bonds between N23...H22N and, to a lesser extent, between N23...H24N. Although 2 is very similar in overall shape to 1, the former adopts a 'locked lock washer' conformation unable to undergo fluctuations, thus possibly hampering a proper recognition by biliverdin reductase.

Epicatechin, catechin, and dimeric procyanidins inhibit PMA-induced NF-kappaB activation at multiple steps in Jurkat T cells

The capacity of the flavan-3-ols [(-)-epicatechin (EC) and (+)-catechin (CT)] and a B dimeric procyanidin (DP-B) to modulate phorbol 12-myristate 13-acetate (PMA)-induced NF-kappaB activation in Jurkat T cells was investigated. The classic PMA-triggered increase in cell oxidants was prevented when cells were preincubated for 24 h with EC, CT, or DP-B (1.7-17.2 microM). PMA induced the phosphorylation of IKKbeta and the subsequent degradation of IkappaBalpha. These events were inhibited in cells pretreated with the flavonoids. PMA induced a 4.6-fold increase in NF-kappaB nuclear binding activity in control cells. Pretreatment with EC, CT, or DP-B decreased PMA-induced NF-kappaB binding activity and the transactivation of the NF-kappaB-driven gene IL-2. EC, CT, and DP-B inhibited, in vitro, NF-kappaB binding to its DNA consensus sequence, but they had no effect on the binding activity of CREB or OCT-1. Thus, EC, CT, or DP-B can influence the immune response by modulating NF-kappaB activation. This modulation can occur at early (regulation of oxidant levels, IKK activation) as well as late (binding of NF-kappaB to DNA) stages of the NF-kappaB activation cascade. A model is presented for possible interactions between DP-B and NF-kappaB proteins, which could lead to the inhibition of NF-kappaB binding to kappaB sites.

Phospholipase activity on N-acyl phosphatidylethanolamines is critically dependent on the N-acyl chain length

We have recently shown that an endogenous phospholipase A2 from bovine erythrocytes does not hydrolyse NAPEs (N-acyl L-alpha-phosphatidylethanolamines), which accumulate remarkably in this system [Florin-Christensen, Suarez, Florin-Christensen, Wainszelbaum, Brown, McElwain and Palmer (2001) Proc. Natl. Acad. Sci. U.S.A. 98, 7736-7741]. Here we investigate the causes underlying this resistance. N-acylation of PE (L-alpha-phosphatidylethanolamine) results in alteration of charge, head-group volume and conformation, the last two features depending on the N-acyl chain length. To evaluate each effect separately, we synthesized NAPEs with selected N-acyl chain length. We found that phospholipase A2 has considerable activity against N-acetyl PE, but is poorly active against N-butanoyl PE and only marginally active against N-hexanoyl PE, whereas the activity is completely lost when N-hexadecanoyl PE is presented as a substrate. On the other hand, N-hexanoyl PE does not inhibit phospholipase A2 activity, suggesting that this substrate fails to enter the hydrophobic channel. Phospholipase C presents a similar, but less sharp pattern. Molecular dynamics simulations of the polar head group of selected NAPEs reveal a substantially increased conformational variability as the N-acyl chain grows. This larger conformational space represents an increased impairment limiting the access of these molecules to the active site. Our data indicate that, whereas a change in charge contributes to diminished activity, the most relevant effects come from steric hindrance related to the growth of the N-acyl chain.

Temperature-induced conformational switch in intestinal fatty acid binding protein (IFABP) revealing an alternative mode for ligand binding

IFABP is a small beta-barrel protein with a short helix-turn-helix motif near the N-terminus that is thought to participate in the regulation of the uptake and delivery of fatty acids. In a previous work, we detected by near UV circular dichroism a reversible conformational transition of this protein occurring between 35 and 50 degrees C in the absence of fatty acids. The addition of the natural ligand oleic acid prevents this phenomenon. In both cases, the overall structure of the beta-barrel is maintained. This thermal transition is also detected by the fluorescent probe bis-anilino naphthalene sulfonic acid (bisANS) but not by its monomer ANS. In the present work, we studied in detail the interaction of each compound with IFABP as a function of temperature and in the absence or in the presence of oleic acid. A contrasting behavior was observed for these probes: (i) IFABP is able to bind two molecules of bisANS but only one molecule of ANS and (ii) oleic acid can fully displace ANS but only partially bisANS. Three independent lines of evidence, namely, fluorescence spectroscopy, circular dichroism, and limited proteolysis, indicate that there is an equilibrium among different conformations of IFABP, which differ in the extent of flexibility of the helical domain. This equilibrium can be shifted by raising temperature. bisANS is able to probe a population of IFABP in an altered state, which is more susceptible to cleavage by clostripain as compared to the apo-form, whereas the conformation of IFABP bound to oleic acid is characteristically more ordered. These results highlight the idea of an enhanced flexibility exhibited by IFABP that bears importance on its transport function, supporting the role of a dynamic entry portal region for the fatty acid ligand.

Probing protein conformation with a minimal photochemical reagent

3H-diazirine (3H-DZN), a photoreactive gas similar in size to water, was used to probe the topography of the surface and inner space of proteins. On photolysis 3H-DZN generates 3H-methylene carbene, which reacts unselectively with its molecular cage, inserting even into C-H bonds. Labeling of bovine alpha-lactalbumin (alpha-LA, MW: 14,200) with 1 mM (3)H-DZN yielded 0.0041 mol CH2/mol of protein, in agreement with the expectation for an unspecific surface-labeling phenomenon. The cooperative urea-induced unfolding of alpha-LA, as monitored by the extent of 3H-methylene labeling, agrees with that measured by circular dichroism spectroscopy in the far and near ultraviolet regions. At 8 M urea, the unfolded state U was labeled 25-30% more than the native state N primarily because of the increase in the accessible surface area (ASA) of the protein occurring upon unfolding. However, this result lies below the approximately 100% increment expected from theoretical estimates of ASA of state U. Among other factors, most likely the existence of a residual structure in U, that involves helices H2 and H4 of the alpha subdomain, might account for this fact, as shown by a comparative analysis of peptide labeling patterns of N and U samples. In this paper, we demonstrate the usefulness of the 3H-methylene labeling method to monitor conformational transitions and map solvent accessibility along the polypeptide sequence, thus opening the possibility of outlining structural features of nonnative states (i.e., denatured states, molten globule). We anticipate that this technique also would help to identify ligand binding and oligomerization sites in proteins.

Mapping the catalytic pocket of phospholipases A2 and C using a novel set of phosphatidylcholines

A set of radioiodinatable phosphatidylcholines (PCs) derivatized with the Bolton-Hunter reagent (BHPCs) was synthesized to probe the substrate recognition and activity of phospholipases. A common feature of this series is the presence of a bulky 4-hydroxyphenyl group at the end of the fatty acyl chain attached to position sn-2. The distance between the end group and the glycerol backbone was varied by changing the length of the intervening fatty acyl chain (3-25 atoms). Except for the shortest, this chain includes at least one amide linkage. The usefulness of this series of substrates as a molecular ruler was tested by measuring the hydrolytic activities of Naja naja naja phospholipase A(2) (PLA(2)) and Bacillus cereus phospholipase C (PLC) in Triton X-100 micelles. The activity of PLA(2) proved to be highly dependent on the length of the fatty acyl chain linker, the shorter compounds (3-10 atoms) being very poor substrates. In contrast, the PLC activity profile exhibited much less discrimination. In both cases, PCs with 16-21 atom chains at position sn-2 yielded optimal activity. We interpret these findings in terms of fatty acyl chain length-related steric hindrance caused by the terminal aromatic group, affecting the activity of PLA(2) and, to a smaller extent, that of PLC. This notion agrees with the more extended recognition of aliphatic chains inside the narrow channel leading to the catalytic site in the former case. Molecular models of these substrates bound to PLA(2) were built on the basis of the crystallographic structure of Naja naja atra PLA(2) complexed with a phospholipid analogue. Docking of these substrates necessarily requires the intrusion of the bulky 4-hydroxyphenyl group inside the binding pocket and also the failure of the amide group to form hydrogen bonds inside the hydrophobic substrate channel.

Exploring the conformation of bilirubins with natural and unnatural analogues: use of positional and bridged isomers of bilirubin IXalpha

Unlike bilirubin IXalpha (1), the isomers bilirubin IXdelta (2) and neobilirubin IXbeta (3) do not require conjugation with glucuronic acid in order to be excreted. A conformational analysis employing an optimized Monte Carlo method and a mixed Monte Carlo stochastic dynamics reveals that isomer 2 exhibits a structure more closed than the well known 'ridge-tile' conformation of 1. The change in the position of both propionic acid chains causes the loss of at least four hydrogen bonds. On the other hand, the change in the configuration of the distal dipyrrinone and the blockage of the lactamic nitrogen by the presence of a bridge in isomer 3 results in an open and more elongated structure, where the chance of hydrogen bond formation in this region is obliterated. The resulting molecular models for these compounds are consistent with 1H NM R, UV-vis, and TLC data.

Temperature-induced conformational transition of intestinal fatty acid binding protein enhancing ligand binding: a functional, spectroscopic, and molecular modeling study

Intestinal fatty acid binding protein (IFABP) undergoes a reversible thermal transition between 35 and 50 degreesC, as revealed by circular dichroism spectroscopy in the near-UV region. For the apoprotein, the molar ellipticity measured at 254 nm (possibly implicating the environment around F17 and/or F55) decreases significantly in this temperature range, while in the holoprotein (bound to oleic acid), this phenomenon is not observed. Concomitantly, an increase in the activity of binding to [14C]oleic acid occurs. Nevertheless, other spectroscopic evidence indicates that the beta-barrel structure, the major motif of this protein, is highly stable up to 70 degreesC. No changes associated with conformation were detected for both structures by fourth-derivative analysis of the UV absorption spectra, circular dichroism in the far-UV region, and intrinsic fluorescence measurements. Further structural information arises from experiments in which binding to the anionic fluorescent probes 1-anilinonaphthalene-8-sulfonic acid (ANS) and its dimer bisANS was examined. The fluorescence intensity of bound ANS diminishes monotonically, whereas that of bisANS increases slightly in the temperature range of 35-50 degreesC. Given the different size of these probes, model building suggests that ANS would be able to sense regions located deeply inside the cavity, while bisANS could also reach the vicinity of the small helical domain of this protein. In light of these results, we believe that this subtle conformational transition of IFABP, which positively influences the binding activity, would involve fluctuations at the peripheral "entry portal" region for the ligand. This interpretation is compatible with the discrete disorder observed in this place in apo-IFABP, as evidenced by NMR spectroscopy [Hodsdon, M. E., and Cistola, D. P. (1997) Biochemistry 36, 1450-1460].

A new photoactivatable reagent capable of transferring a radiolabel to target proteins. Application to the human growth hormone-rat liver prolactin receptor interaction

A new photoactivatable cross-linking reagent, 1-(2'-dithiopyridyl)-2-(5'-azidosalicylamido)ethane (ASDPE), was synthesized. This probe can be easily labeled with 125I in the azidosalicylamido ring and contains an activated disulfide bridge. After reaction of [125I]ASDPE with proteins, the radiolabeled moiety of the probe becomes attached to cysteine residues. Upon partial reduction of human growth hormone (hGH) with dithiothreitol, its C-terminal disulfide bond between residues 182 and 189 was cleaved and the nascent thiol groups were modified with [125I]ASDPE to yield [125I]ASET-hGH [1-(thio-hGH)-2-(3'-[125I]iodo-5'-azidosalicylamido)ethane]. After binding of this hormone derivative to rat liver microsomes, followed by photolysis and subsequent reduction of disulfide bridges, the specific transfer of the radiolabeled moiety to prolactin receptor (PRL-R) was achieved. Partial purification of the radiolabeled receptor by size exclusion chromatography was performed. We anticipate that [125I]ASDPE will be generally useful in pursuing structural and functional studies of target proteins which interact specifically with protein ligands.

A membrane protein associated with the prolactin receptor. Studies with a photoactivatable human growth hormone derivative

Prolactin receptor from rat liver (PRL-R, 42 kDa) was cross-linked to a radiolabeled azidophenacyl derivative of human growth hormone ([125I]AP-hGH) to yield a 63 kDa adduct. In addition, a protein of Mr 50-52 K was detected as a 73 kDa complex. Microsomes incubated with either (a) increasing amounts of [125I]AP-hGH, or (b) a fixed amount of photoprobe and increasing concentrations of unlabeled hGH, showed that the 73/63 kDa band intensity ratio remains constant (0.71-0.77). Once transferred onto nitrocellulose membranes, only the 42 kDa protein is able to bind [125I]AP-hGH or [125I]hGH. Two anti-PRL-R monoclonal antibodies fail to cross-react with proteins of Mr 50-52 K. In membranes solubilized with 3-[(3-cholamidopropyl)-dimethylammonio]-1-propanesulfonate (CHAPS), a significantly lower amount of the 73 kDa complex is detected. Thus, the 50-52 kDa protein appears to be structurally unrelated to, but is presumably associated with the PRL-R. The 73 kDa complex is also detected under low membrane fluidity conditions (1 degree C), indicating that PRL-R associates to this 50-52 kDa protein prior to hormone binding. Perfusion of rat liver with [125I]AP-hGH shows that this associated protein accompanies the receptor along its intracellular pathway.

Micellar lipoproteins as the possible storage and translocation form of intracellular diacylglycerol

Previous work indicated that diacylglycerol (DG) molecules translocate across the cytoplasm of mammalian cells, a process relevant to the signalling role of this lipid as protein kinase C activator. Here we investigated the possible mechanism underlying DG translocation. We examined the interaction between 1,2-di-[1-14C]oleoyl-sn-glycerol and rat liver cytosol (rlc) using assays based on Lipidex-1000 and on coelution on Sepharose CL 6B. We measured high DG binding activity and found that it resides in cytosolic proteins and not in cytosolic lipids. Chromatography of rlc proteins on Sepharose CL 6B showed profiles in which the activity measured by either method coincided. Further, we showed that the DG-rlc protein interaction results in the stabilization of DG in a micellar form, eluting in the void volume of Sepharose CL 6B. Such stabilized micelles are reminiscent of insect lipophorins and may represent a new, thus far unrecognized, mode of lipid transport within living cells.

Probing the conformation of bilirubins with monopropionic analogs: a biological, spectroscopic, and molecular modeling study

The in vivo metabolism of a bilirubin analog substituted with a propionic acid chain in C8 (5) showed that it is excreted in bile conjugated with glucuronic acid, while a positional isomer substituted with a propionate in C7 (6) is excreted in bile without conjugation. A conformational analysis employing an optimized Monte Carlo method and a mixed Monte Carlo/stochastic dynamics reveals that isomer 5 adopts a 'ridge tile' conformation, stabilized by the presence of three intramolecular hydrogen bonds. On the contrary, isomer 6 exhibits a more closed structure, where impairment in the formation of at least one of the hydrogen bonds occurs. These theoretical predictions agree well with 1H NMR, UV-vis, and TLC data.

The membrane topology of the amino-terminal domain of the red cell calcium pump

A systematic study of the membrane-associated regions in the plasma membrane Ca2+ pump of erythrocytes has been performed by hydrophobic photolabeling. Purified Ca2+ pump was labeled with 3-(trifluoromethyl)-3-(m-[125I]iodophenyl)-diazirine ([125I]TID), a generic photoactivatable hydrophobic probe. These results were compared with the enzyme labeled with a strictly membrane-bound probe, [3H]bis-phosphatidylethanolamine (trifluoromethyl) phenyldiazirine. A significant light-dependent labeling of an M(r) 135,000-140,000 peptide, corresponding to the full Ca2+ pump, was observed with both probes. After proteolysis of the pump labeled with each probe and isolation of fragments by SDS-PAGE, a common pattern of labeled peptides was observed. Similarly, labeling of the Ca2+ pump with [125I]TID, either in isolated red blood cell membranes or after the enzyme was purified, yields a similar pattern of labeled peptides. Taken together, these results validate the use of either probe to study the lipid interface of the membrane-embedded region of this protein, and sustain the notion that the conformation of the pump is maintained throughout the procedures of solubilization, affinity purification, and reconstitution into proteoliposomes. In this work, we put special emphasis on a detailed analysis of the N-terminal domain of the Ca2+ pump. A labeled peptide of M(r) 40,000 belonging to this region was purified and further digested with V8 protease. The specific incorporation of [125I]TID to proteolytic fragments pertaining to the amino-terminal region indicates the existence of two transmembrane stretches in this domain. A theoretical analysis based on the amino acid sequence 1-322 predicts two segments with high probability of membrane insertion, in agreement with the experimental data. Each segment shows a periodicity pattern of hydrophobicity and variability compatible with alpha-helical structure. These results strongly suggest the existence of a transmembrane helical hairpin motif near the N-terminus of the Ca2+ pump.

Detection and characterization of an ovine placental lactogen stable intermediate in the urea-induced unfolding process

The urea-induced equilibrium unfolding of ovine placental lactogen, purified from ovine placenta, was followed by size-exclusion chromatography, far-UV CD, and intrinsic tryptophan fluorescence. The data obtained by each of these methods showed a poor fit to a two-state model involving only a native and an unfolded form. A satisfactory fit required, instead, a model that involved a stable, partially folded form in addition to the native and unfolded ones. The results obtained from the best-fitting theoretical curves for the three-state model indicated that this intermediate state, which is the predominant species in solution at 3.6 M of urea activity, is compact, largely alpha-helical, and changes considerably the native-like tertiary packing around its tryptophan residues. These findings suggest that this stable intermediate exhibits properties similar to those that characterize the molten globule state.

Interaction of unsaturated fatty acids with the red blood cell Ca(2+)-ATPase. Studies with a novel photoactivatable probe

Unsaturated fatty acids, such as oleic acid, increase both the affinity for Ca2+ and the maximum effect of the Ca(2+)-ATPase of red blood cells [Niggli et al. (1981) J. Biol. Chem. 256, 8588-8592]. With the aim of examining the structural and kinetic details of the interaction between unsaturated fatty acids and the enzyme, we designed and synthesized 8-(5'-azido-O-hexanoylsalicylamido)octanoic acid (AS86), a photoactivatable analogue of unsaturated fatty acids. AS86, interacting noncovalently with the enzyme, shares with oleic acid the following properties: (i) it binds reversibly to the plasma membrane Ca(2+)-ATPase; (ii) in the absence of calmodulin, AS86 shows a biphasic behavior; i.e., at low concentrations it increases the affinity for Ca2+ and the maximum velocity of the enzyme, while at higher concentrations it decreases the maximum velocity; (iii) in the presence of calmodulin, AS86 increases slightly the affinity for Ca2+ and decreases the maximum velocity of the Ca2+ pump; and (iv) AS86 inhibits the activity of the enzyme devoid of its calmodulin-binding domain after proteolysis. When the reagent is covalently bound to the native enzyme, and then activated by calmodulin, increasing amounts of AS86 decrease the maximum velocity along a hyperbolic curve without modifying the apparent affinity for Ca2+. These results could be explained by the eventual existence of two different kind of sites recognizing the reagent: one influencing the affinity for Ca2+ and the other inhibitory of the calmodulin effects. When covalently bound, AS86 exerts its inhibitory effects upon the enzyme lacking the calmodulin-binding domain, thus reflecting that this action is promoted by interaction with a site lying outside this region. The purified enzyme is susceptible to be tagged with 125I-AS86. Both the inhibitory effect on the calmodulin-dependent enzymic activity after covalent binding of AS86 and the photoadduct formation between the enzyme and 125I-AS86 are impaired by the presence of oleic acid in a concentration-dependent fashion. Recognition of photoreactive fatty acid analogues by the purified enzyme could be useful to provide further insight on the location of the interacting sites.

Differential hydrolysis of immobilized phosphatidylcholines by phospholipases A2 and C

A novel phospholipid, 1-fatty acyl-2-(12-aminododecyl) phosphatidylcholine (APC), was synthesized and reacted with two different activated agarose matrices, differing in the spacer arm length: N-hydroxysuccinimidylester agarose (1-atom spacer arm) and N-hydroxysuccinimidylester-6-aminohexanoic acid agarose (8-atom spacer arm). Both immobilized phosphatidylcholines were readily degraded by Bacillus cereus phospholipase C at similar rates. By contrast, Crotalus adamanteus phospholipase A2 hydrolyzed long-spacer arm phosphatidylcholine, but had less than one tenth of the activity towards the short-spacer arm one. These results are interpreted in terms of a chain length-related steric hindrance caused by the matrix, affecting phospholipase A2 but not phospholipase C activity, supporting the view that the first involves a deeper burrowing of the substrate into the enzyme molecule.

Identification of transmembrane domains of the red cell calcium pump with a new photoactivatable phospholipidic probe

The membrane-associated regions of the human erythrocyte Ca2+ pump were investigated by hydrophobic photolabeling. Purified Ca2+ pump was reconstituted in asolectin vesicles loaded with [3H]DIPETPD, a photochemical probe designed to label deeply into the hydrophobic core of the lipid bilayer (Delfino et al. J. Am. Chem. Soc. 115, 3458-3474, 1993). After photolysis and SDS-PAGE analysis, a significant light-dependent labeling of the Ca2+ pump was found. Controlled proteolysis of the photoadduct with trypsin or protease V8 followed by SDS-PAGE and immunoblotting yielded individual labeled fragments. The labeling pattern indicated the existence of three sequential clusters of transmembrane regions, consistent with the current model for the topography of this enzyme.

Isolation and characterization of two new functional subtypes of HLA-B35

Human minor histocompatibility antigen-specific, HLA-B*3501-restricted cytotoxic T-cell clones were assayed on a panel of 25 different target cells previously typed by serology as HLA-B35. Cells from 6 donors were not killed and cells from 2 of these were further studied by molecular cloning to characterize their HLA class I alleles. Two new HLA-B35 subtypes were identified. The sequence of one of them differs from B*3501 by one nucleotide change at codon 156, replacing a Leu for an Arg. The sequence of the other new subtype also shows a single nucleotide change compared to B*3501, with Gly-->Val substitution at residue 16. With these new variants, the allelic complexity of HLA-B35 extends now to eight subtypes.

New patterns of diacylglycerol metabolism in intact cells

The metabolism of di[1-14C]octanoylglycerol metabolism was examined in four cell lines: NIH 3T3 fibroblasts, BHK cells, Pam 212 keratinocytes and WEHI 3BD+ cells. We found the direct conversion of 1,2-di[1-14C]octanoyl-sn-glycerol ([14C]diC8) into dioctanoylphosphatidylcholine and dioctanoylacylglycerol, but no formation of phosphatidylinositol. The [14C]diC8 also underwent lipolytic breakdown. In contrast, 1-[1-14C]oleoyl-2-acetyl-sn-glycerol was metabolized exclusively by lipolysis. Our findings support a new scheme for the metabolic termination of diacylglycerol signals.

Metabolic fate of plasma membrane diacylglycerols in NIH 3T3 fibroblasts

We have examined the metabolism of three radiolabeled 1,2-diacylglycerols (DGs) in NIH 3T3 fibroblasts. Since the lipids used are not appreciably taken up by the cells, we used a phosphatidylserine (PS)-based liposome fusion system to rapidly associate the lipid species with the plasma membrane. When 1,2-[1-14C]dioleoyl-sn-3-glycerol ([14C]DOG) is delivered in this way, it is rapidly converted predominantly to phosphatidylcholine (PC) and triacylglycerol (TG) and to a lesser extent, to monoacylglycerol (MG) and fatty acids (FA), as well as phosphatidic acid (PA) and phosphatidylinositol (PI). We present evidence that [14C] DOG is largely utilized as an intact molecule rather than being broken down to FA and then incorporated to cell lipids. Examination of the metabolism of 1-stearoyl-2-[1-14C]myristoyl-sn-3-glycerol ([14C]SMG) and 1-stearoyl-2-arachidonoyl-sn-3-glycerol ([14C]SAG) reveal important differences. Both produce substantial labeling of PC but [14C]SMG gives rise to the highest proportion of TG and the lowest of PA and PI, whereas [14C]SAG yields the opposite pattern. When phosphatidic acid labeled on its glycerol backbone (1,2-dioleoyl-sn-[U-14C] glycero-3-phosphate) was supplied to the cells via the liposomes, rapid appearance of labeled DG was found which then decreased with concomitant labeling of cellular PC and TG. Only small amounts of the glycerol backbone were recovered in PI. Our experiments identify three types of processes involved in the metabolism of plasma membrane DGs: (i) transferase-catalyzed conversions to PC and TG, (ii) lipolytic breakdown to MG and FA, and (iii) phosphorylation to PA and then conversion to PI. The relative proportions of each DG species converted to these different products are strongly dependent on the fatty acyl composition of the particular DG molecular species, even though formation of PC is the major event in all cases. Since DGs are important second messengers, our study supports the view that conversion to PC and TG can play a key role in DG signal attenuation.

Conformation-dependent cleavage of staphylococcal nuclease with a disulfide-linked iron chelate

We report the synthesis and evaluation of (EDTA-2-aminoethyl) 2-pyridyl disulfide. By using this easily prepared cysteine-specific hydrophilic reagent, an ethylenediaminetriacetic acid-Fe3+ complex (EDTA-Fe) was covalently attached to a single genetically engineered cysteine residue in staphylococcal nuclease. Upon addition of the iron reductant ascorbate, the nuclease-EDTA-Fe conjugate underwent a protein self-cleavage reaction mediated by reactive oxygen species. Sequence analysis of the products indicated that cleavage occurs close in tertiary structure to the EDTA-Fe attachment site. In the presence of denaturants, the cleavage pattern changes and the reaction is limited to residues proximal in sequence to the cysteine attachment site. These results indicate that intramolecular protein cleavage reactions mediated by EDTA-Fe can be used to evaluate changes in protein conformation. The reagent described should be a useful tool in the structural mapping of nonnative protein states populated at equilibrium, such as the molten globule, that are frequently refractory to conventional structure analysis.

The HA2 subunit of influenza hemagglutinin inserts into the target membrane prior to fusion

The interaction between influenza virus and target membrane lipids during membrane fusion was studied with hydrophobic photoactivatable probes. Two probes, the newly synthesized bisphospholipid diphosphatidylethanolamine trifluoromethyl [3H]phenyl diazirine and the phospholipid analogue 1-palmitoyl-2(11-[4-[3-(trifluoromethyl)diazirinyl]phenyl]-[2-3H]- undecanoyl]-sn-glycero-3-phosphocholine (Harter, C., Bächi, T., Semenza, G., and Brunner , J. (1988) Biochemistry 27, 1856-1864), were used. Both labeled the HA2 subunit of the virus at low pH. By measuring virus-liposome interactions at 0 degrees C, it could be demonstrated that HA2 was inserted into the target membrane prior to fusion. As we have recently demonstrated, at this temperature, exposure of the fusion peptide of HA2 takes place within 15 s after acidification, but fusion does not start for 4 min (Stegmann, T., White, J. M., and Helenius, A. (1990) EMBO J. 9, 4231-4241). HA2 was labeled at least 2 min before fusion. No labeling of the HA1 subunit was seen. These data indicate that fusion is triggered by a direct interaction of the HA2 subunit of a kinetic intermediate form of HA with the lipids of the target membrane. Most likely, it is the fusion peptide of HA2 that is inserted into the target membrane. Just before fusion, HA is thus an integral membrane protein in both membranes. In contrast, the bromelain-derived ectodomain of HA was labeled by 1-palmitoyl-2(11-[4-[3-(trifluoromethyl)diazirinyl]phenyl]- [2-3H]undecanoyl)-sn-glycerol-3-phosphocholine at low pH but not by diphosphatidylethanolamine trifluoromethyl [3H]phenyl diazirine. This indicates that insertion of the fusion peptide of the bromelain-derived ectodomain of HA into a membrane differs from that of viral HA during fusion.

Purification of gramicidin A

A simple chromatographic purification of the naturally occurring ion channel-forming pentadecapeptide gramicidin A (gA) is presented. This procedure allows gA to be isolated in gram quantities from the commercially available mixture of isomers after chromatography on silica gel. The gramicidin A obtained in this manner is greater than 95% pure as determined by 1HNMR, HPLC, and amino acid analysis.

Transmembrane channels based on tartaric acid-gramicidin A hybrids

The gramicidin A transmembrane channel is believed to consist of two head-to-head beta helices. Computer-generated models were used to formulate the structure of new single-chain channel molecules based on the gramicidin motif. The chemical synthesis of two tartaric acid-gramicidin A hybrids and single-channel analyses of their conducting properties are reported. These studies illustrate the rational design and synthesis of long-lived channels with tunable conductance properties and provide support for current molecular models of the natural (dimeric) gramicidin channel.

Carboxylate groups in bovine somatotropin involved in growth promoting activity. Theoretical models based upon individual kinetic constants to interpret the activity decay after chemical modification

Modification of approximately one fifth of the carboxylate groups in bovine somatotropin with a water soluble carbodiimide caused loss of growth promoting potency pointing to the existence of residues related to the hormonal activity among those belonging to a fast reacting set. A sigmoidal curve was obtained whether the inactivation process was referred to reaction time or degree of modification. Isoelectrofocusing of derivatives released the native hormone from responsibility for the biological potency exerted by preparations with 1.5-2.6 modified carboxylate groups. Examination of the individual reaction kinetics of the 11 fast reacting residues, in turn, excluded the possibility of the sigmoidal character of the inactivation curve being caused by a nonexponential disappearance of essential residues, as a possible consequence of the chemical modification of others. According to synthetic models, the experimental curve may be the consequence of the effect of cumulative modification of 2 or 3 out of a set of 3 to 8 relevant residues.