Tryptophan fluorescence study on the interaction of the signal peptide of the Escherichia coli outer membrane protein PhoE with model membranes

The interaction of the signal peptide of the Escherichia coli outer membrane protein PhoE with different phospholipid vesicles was investigated by fluorescence techniques, using a synthetic mutant signal peptide in which valine at position -8 in the hydrophobic sequence was replaced by tryptophan. First it was established that this mutation in the signal sequence of prePhoE does not affect in vivo and in vitro translocation efficiency and that the biophysical properties of the synthetic mutant signal peptide are similar to those of the wild-type signal peptide. Next, fluorescence experiments were performed which showed an increase in quantum yield and a blue shift of the emission wavelength maximum upon interaction of the signal peptide with lipid vesicles, indicating that the tryptophan moiety enters a more hydrophobic environment. These changes in intrinsic fluorescence were found to be more pronounced in the presence of phosphatidylglycerol (PG) or cardiolipin (CL) than with phosphatidylcholine (PC). In addition, quenching experiments demonstrated a shielding of the tryptophan fluorescence from quenching by the aqueous quenchers iodide and acrylamide upon interaction of the signal peptide with lipid vesicles, a shielding in the case of acrylamide that was more pronounced in the presence of negatively charged lipids. Finally it was found that acyl chain brominated lipids incorporated into phospholipid bilayers were able to quench the tryptophan fluorescence of the signal peptide, with the quenching efficiency in CL vesicles being much higher than in PC vesicles. The results clearly demonstrate that the PhoE signal peptide interacts strongly with different lipid vesicles.(ABSTRACT TRUNCATED AT 250 WORDS)     

The interaction of Abrus precatorius agglutinin with saccharides as analyzed by fluorescence spectroscopy

The binding of saccharides to Abrus precatorius agglutinin (APA) was analyzed by fluorescence spectroscopy. Upon binding of specific saccharides, the fluorescence emission maximum of APA (338 nm) shifted to shorter wavelength by 5 nm, owing to the change in the environment of tryptophan. By analyzing the change in the fluorescence intensity at 338 nm as a function of concentration of saccharides, the association constants for binding of saccharides to APA were determined. The results suggest that in the saccharide binding site on each B-chain of APA, there may be a site which interacts with the saccharide residue linked to galactopyranoside at the non-reducing end, in addition to the site which recognizes the galactopyranosyl residue. Fluorescence quenching data indicate that 8 out of 24 tryptophans in APA are located at or near the surface of the protein molecule and are available for quenching with both KI and acrylamide, and 10 tryptophans are involved in the environment to which acrylamide has access but KI does not. Binding of lactose to APA reduced by 4 the number of tryptophan residues accessible to quenchers. Based on the results, it is suggested that the tryptophan residues at the saccharide binding site on each B-chain of APA are present on the surface of the APA molecule, and they are shielded from quenching by KI and acrylamide upon binding with specific saccharides.     

A spectrofluorometric study of the environment of tryptophans in bacteriorhodopsin

The emission spectrum of intact purple membranes of Halobacterium halobium has a very short wavelength position (the main maximum at 314 nm) and can be fitted by two spectral components, one of which (component A) corresponds to the fluorescence of buried tryptophan residues located in a highly hydrophobic rigid environment (like the single tryptophan residue in azurin), the other (component I) being due to the emission of buried tryptophan residues located in a rather polar environment. Treatment of bacteriorhodopsin by NaBH4, fragmentation of the membranes and thermal formation of vesicles result in a decrease in the contribution of component A, an increase in that of component I and the appearance of spectral components corresponding to the emission of surface tryptophan residues. Temperature induces at least two distinct changes of the fluorescence parameters of the protein: one change occurs from 45 to 65 degrees C. the other from 65 to 90 degrees C. The spectral changes correlate with the peaks of heat sorption caused by thermal transitions in the purple membrane structure and conformational changes in the protein structure. Alkaline denaturation of bacteriorhodopsin registered by tryptophan fluorescence begins at pH > 11.0.     

The structure and orientation of class-A amphipathic peptides on a phospholipid bilayer surface

The amphipathic α-helix is a recognised structural motif that is shared by membrane-associating proteins and peptides of diverse function. The aim of this paper is to determine the orientation of an α-helical amphipathic peptide on the bilayer surface. We use five amphipathic 18-residue peptide analogues of a class A amphipathic peptide that is known to associate with a bilayer surface. Tyrosine and tryptophan are used as spectroscopic probes to sense local environments in the peptide in solution and when bound to the surface of unilamellar phosphatidylcholine vesicles. In a series of peptides, tryptophan is moved progressively along the sequence from the nonpolar face (positions 3, 7, 4) to the polar face of the peptide (positions 2, 12). The local environment of the tryptophan residue at each position is determined using fluorescence spectroscopy employing quantum yield, and the wavelength of the emission maximum as indicators of micropolarity. The exposure of the tryptophan residues at each site is assessed by acrylamide quenching. On association with vesicles, the tryptophan residues at positions 3, 7 and 14 are in nonpolar water-shielded environments, and the tryptophan at position 12 is in an exposed polar environment. The tryptophan at position 2, which is located near the bilayer-water interface, exhibits intermediate behaviour. Analysis of the second-derivative absorption spectrum confirmed that the tyrosine residue at position 7 is in a nonpolar water-shielded environment in the peptide-lipid complex. We conclude that these class A amphipathic peptides lie parallel to the lipid surface and penetrate no deeper than the ester linkages of the phospholipids. Received: 8 April 1998 / Revised version: 6 July 1998 / Accepted: 7 August 1998     

Fluorescence spectroscopic studies on tryptophan at the saccharide-binding site of castor bean hemagglutinin

The environment of tryptophan in castor bean hemagglutinin (CBH) was analyzed by fluorescence spectroscopy with regard to saccharide binding. Upon binding of specific saccharides, the fluorescence maximum of 333 nm of CBH shifted to a wavelength 2 nm shorter, owing to the change in the environment of tryptophan at the saccharide-binding site. By analyzing the change in the fluorescence intensity at 320 nm as a function of concentration of saccharides, the association constants for binding of saccharides to CBH were determined. The results suggest that the saccharide-binding site on each B-chain is actually composed of a subsite with which the saccharide residue linked to galactopyranoside at the non-reducing end can interact, and another site which recognizes the galactopyranoside moiety. Quenching data indicated that five out of 22 tryptophans in CBH are surface-localized and are available for quenching with both KI and acrylamide, and three other tryptophans are buried and are available only to acrylamide. Binding of raffinose to CBH decreased by 2 the number of tryptophan residues accessible to quenchers in the CBH molecule. We speculate that raffinose binds to CBH in such a manner as to shield the tryptophan located at the subsite from quenching by KI and acrylamide. The results also suggest that the tryptophan residue at the saccharide-binding site on each B-chain is localized near the surface, and present in the positively charged environment.     

Fluorescence analysis of tryptophan-containing variants of the LamB signal sequence upon insertion into a lipid bilayer

To investigate the interaction of the LamB signal sequence with lipid bilayers, we have synthesized three tryptophan-containing analogues of the wild-type signal peptide. The tryptophan residues were used as intrinsic fluorescent probes of the N-terminal (position 5), central (position 18), and C-terminal (position 24) regions of the 25-residue peptide. The tryptophan substitutions did not significantly alter the physical properties of the wild-type signal peptide. In the presence of lipid vesicles which mimic the composition of the Escherichia coli inner membrane, the peptides adopt alpha-helical structure, and the tryptophan fluorescence emission maximum is shifted to shorter wavelength, indicating that the peptides insert into the acyl chain region of the lipid bilayer. Fluorescence quenching by soluble, aqueous-phase (I-), and membrane-resident (nitroxide-labeled lipids) quenchers was used to locate the tryptophans in each peptide within the bilayer. The C-terminus was interfacial while the central region of the signal sequence was deeply buried within the acyl chain region of the bilayer. The tryptophan at position 5 was buried but less deeply than the tryptophan at position 18. This topology is consistent with either a looped or a transmembrane orientation of signal peptide. However, either structure must accommodate the high helical content of the peptides in vesicles. These results indicate that the LamB signal sequence spontaneously inserts into the acyl chain region of lipid membranes in the absence of any of the proteins involved in protein secretion.     

The use of fluorescence spectroscopy for identification of A- and B-thrombin chains during their chromatographic separation

The separation of A- and B-chains of human thrombin has been performed by gel filtration on Sephadex G-100 under the reduction of disulphide bonds with dithiothreitol. Identification of A- and B-chains has been provided by measurements of the fluorescence intensity of fractions at 310 nm and 350 nm which are near the maximum positions of tyrosine and tryptophan fluorescence, respectively. The appearance of A-chain was monitored by an increase of the ratio of Ifl310/Ifl350 greater than 2. The fluorescence spectrum of A-chain has maximum position at 304 nm, which is characteristic of tyrosine fluorescence. The fluorescence spectrum of B-chain has maximum position at 347.5 nm which corresponds to fluorescence of tryptophan residues. The identification of A- and B-chains has been confirmed by the gel electrophoresis data.     

Interaction of dystrophin rod domain with membrane phospholipids. Evidence of a close proximity between tryptophan residues and lipids

Dystrophin is assumed to act via the central rod domain as a flexible linker between the amino-terminal actin binding domain and carboxyl-terminal proteins associated with the membrane. The rod domain is made up of 24 spectrin-like repeats and has been shown to modify the physical properties of lipid membranes. The nature of this association still remains unclear. Tryptophan residues tend to cluster at or near to the water-lipid interface of the membrane. To assess dystrophin rod domain-membrane interactions, tryptophan residues properties of two recombinant proteins of the rod domain were examined by (1)H NMR and fluorescence techniques in the presence of membrane lipids. F114 (residues 439-553) is a partly folded protein as inferred from (1)H NMR, tryptophan fluorescence emission intensity, and the excited state lifetime. By contrast, F125 (residues 439-564) is a folded compact protein. Tryptophan fluorescence quenching shows that both proteins are characterized by structural fluctuations with their tryptophan residues only slightly buried from the surface. In the presence of negatively charged small vesicles, the fluorescence characteristics of F125 change dramatically, indicating that tryptophan residues are in a more hydrophobic environment. Interestingly, these modifications are not observed with F114. Fluorescence quenching experiments confirm that tryptophan residues are shielded from the solvent in the complex F125 lipids by a close contact with lipids. The use of membrane-bound quenchers allowed us to conclude that dystrophin rod domain lies along the membrane surface and may be involved in a structural array comprising membrane and cytoskeletal proteins as well as membrane lipids.     

Shiga toxin B-subunit sequential binding to its natural receptor in lipid membranes

Shiga toxin B-subunit (STxB), a protein involved in the cell-binding and intracellular trafficking of Shiga holotoxin, binds to a specific glycolipid, the globotriaosyl ceramide (Gb₃). Tryptophan residues of STxB, located at the protein-membrane interface, allow one to study its interaction with model membranes by means of spectroscopic methods with no need for chemical derivatisation with a fluorophore. The protein emits maximally around 346 nm and a blue shift of about 8 nm, as well as the occurrence of changes in the emission fluorescence intensity spectra, is indicative of insertion and partition into the membrane. However, the interaction seems to take place without pentamer dissociation. Acrylamide quenching experiments confirm tryptophan residues become less exposed to solvent when in the presence of vesicles, and the use of lipophilic probes suggests that they are located in a shallow position near the water/membrane interface. Fluorescence intensity and lifetime measurements upon STxB titration with Gb₃-containing vesicles suggest a complex STxB/Gb₃ docking mechanism involving static quenching in the later stages. Based on our observations, a model of the protein-membrane interaction is proposed and the STxB membrane partition and binding constants were calculated.     

Shiga toxin B-subunit sequential binding to its natural receptor in lipid membranes

Shiga toxin B-subunit (STxB), a protein involved in the cell-binding and intracellular trafficking of Shiga holotoxin, binds to a specific glycolipid, the globotriaosyl ceramide (Gb(3)). Tryptophan residues of STxB, located at the protein-membrane interface, allow one to study its interaction with model membranes by means of spectroscopic methods with no need for chemical derivatisation with a fluorophore. The protein emits maximally around 346 nm and a blue shift of about 8 nm, as well as the occurrence of changes in the emission fluorescence intensity spectra, is indicative of insertion and partition into the membrane. However, the interaction seems to take place without pentamer dissociation. Acrylamide quenching experiments confirm tryptophan residues become less exposed to solvent when in the presence of vesicles, and the use of lipophilic probes suggests that they are located in a shallow position near the water/membrane interface. Fluorescence intensity and lifetime measurements upon STxB titration with Gb(3)-containing vesicles suggest a complex STxB/Gb(3) docking mechanism involving static quenching in the later stages. Based on our observations, a model of the protein-membrane interaction is proposed and the STxB membrane partition and binding constants were calculated.     

Incorporation of the antimicrobial protein seminalplasmin into lipid bilayer membranes

The interaction between seminalplasmin, an antimicrobial protein from bull semen, and lipid bilayers has been investigated. The fluorescence of the single tryptophan residue of the protein was measured. In the presence of phosphatidylcholine or phosphatidic acid bilayer vesicles the fluoresence maximum was shifted to shorter wavelengths, indicating transfer of the tryptophan to a more apolar environment. Circular dichroism spectra show an increased -helical content for the protein in the presence of lipid. Quenching experiments clearly show the incorporation of the protein with the tryptophan localized near the bilayer surface. The shift of the tryptophan fluorescence emission was used to monitor the lipid phase transition in phosphatidylcholine membranes.Abbreviations TEMPOL 2,2,6,6-Tetramethyl-4-hydroxy-piperidine-1-oxyl - DMPC 1,2-Dimyristoylphosphatidylcholine - DMPA 1,2-Dimyristoylphosphatidic acid - SL 5 2-(3-Carboxypropyl)-4,4-dimethyl-2-tridecyl-3-oxazolidinoxyl - SL 12 2-(10-Carboxydecyl)-4,4-dimethyl-2-hexyl-3-oxazolinoxyl     

Fluorescence-quenching-resolved spectra of melittin in lipid bilayers

The interaction of bee venom melittin with dimyristoylphosphatidylcholine (DMPC) unilamellar vesicles has been studied by means of fluorescence quenching of the single tryptophan residue of the protein, at lipid-to-peptide ratio, Ri = 50 and at high ionic strength (2 M NaCl). The method of fluorescence-quenching-resolved spectra (FQRS), applied in this study with potassium iodide as a quencher, enabled us to decompose the tryptophan emission spectrum of liposome-bound melittin into components, at temperatures above as well as below the main phase transition temperature (Tt) of DMPC. One of the two resolved spectra exhibits maximum at 342 and 338 nm for experiments above and below Tt, respectively, and is similar to the maximum of tryptophan emission found for tetrameric melittin in solution (340 nm). This spectrum is characterized by the Stern-Volmer quenching constant, Ksv, of about 4 M-1 and it represents the fraction of melittin molecules whose tryptophan residues are exposed to the solvent to a degree comparable with tetrameric species in solution. The other spectrum component, corresponding to the quencher-inaccessible fraction of tryptophan molecules (Ksv = 0 M-1) has its maximum blue-shifted up to 15 nm, indicating a decrease in polarity of the environment. For experiments above Tt, the blue spectrum component revealed the excitation-wavelength dependence, originating probably from the relaxation processes between the excited tryptophan molecules and lipid polar head groups. We conclude that melittin bound to DMPC liposomes exists in two lipid-associated forms; one, with tryptophan residues exposed to the solvent and the other, penetrating the membrane interior, with tryptophan residues located in close proximity to the phospholipid polar head groups of the outer vesicle lipid layer. We also discuss our data with current models of melittin-bilayer interactions.     

The binding of the B-chain of ricin to Burkitt lymphoma cells. A new approach to ligand-receptor interaction studies

It is shown that conformational changes of receptor proteins brought about by binding of a ligand induce changes in the lipid environment of the receptor that can be monitored by fluorescent lipid probes. On this basis a new approach to studies of ligand-receptor binding is proposed. Using the interaction of the ricin B-chain with Burkitt lymphoma cells as an example and fluorescent labelled sphingomyelin as a probe, the ligand-induced changes of fluorescence anisotropy were shown to be concentration-dependent and to permit determination of the binding constant and the number of receptor-binding sites. The method was found to be specific and highly sensitive, allowing detection of the action of one RB molecule per cell. Scatchard analysis of the binding of 125I-RB demonstrated the presence on the cell surface of two binding sites with Kd approximately 10(-10) and approximately 10(-8) M, respectively. Only the high-affinity sites were detected by the fluorescence technique. Saturation of these sites resulted in maximum inhibition of protein synthesis.     

Tryptophan-lipid interactions in membrane protein folding probed by ultraviolet resonance Raman and fluorescence spectroscopy

Aromatic amino acids of membrane proteins are enriched at the lipid-water interface. The role of tryptophan on the folding and stability of an integral membrane protein is investigated with ultraviolet resonance Raman and fluorescence spectroscopy. We investigate a model system, the β-barrel outer membrane protein A (OmpA), and focus on interfacial tryptophan residues oriented toward the lipid bilayer (trp-7, trp-170, or trp-15) or the interior of the β-barrel pore (trp-102). OmpA mutants with a single tryptophan residue at a nonnative position 170 (Trp-170) or a native position 7 (Trp-7) exhibit the greatest stability, with Gibbs free energies of unfolding in the absence of denaturant of 9.4 and 6.7 kcal/mol, respectively. These mutants are more stable than the tryptophan-free OmpA mutant, which exhibits a free energy of unfolding of 2.6 kcal/mol. Ultraviolet resonance Raman spectra of Trp-170 and Trp-7 reveal evolution of a hydrogen bond in a nonpolar environment during the folding reaction, evidenced by systematic shifts in hydrophobicity and hydrogen bond markers. These observations suggest that the hydrogen bond acceptor is the lipid acyl carbonyl group, and this interaction contributes significantly to membrane protein stabilization. Other spectral changes are observed for a tryptophan residue at position 15, and these modifications are attributed to development of a tryptophan-lipid cation-π interaction that is more stabilizing than an intraprotein hydrogen bond by ∼2 kcal/mol. As expected, there is no evidence for lipid-protein interactions for the tryptophan residue oriented toward the interior of the β-barrel pore. These results highlight the significance of lipid-protein interactions, and indicate that the bilayer provides more than a hydrophobic environment for membrane protein folding. Instead, a paradigm of lipid-assisted membrane protein folding and stabilization must be adopted.     

Interaction of glucagon with dimyristoyl glycerophosphocholine

Glucagon can form amphipathic helices and can interact with dimyristoyl glycerophosphocholine at temperatures below the phase transition leading to a shift in the fluorescence emission maximum of tryptophan from 350 to 338 nm and a 3-fold enhancement of fluorescence intensity as well as a change in the polarization of fluorescence. The circular dichroism properties of the lipid-associated glucagon indicates that it has an increased content of alpha-helix. The phase transition temperature of the lipid as monitored by pyrene excimer fluorescence is not altered by interaction with glucagon although at higher glucagon/lipid ratios a decrease in excimer formation is noted at low temperature. Above the phase transition temperature, the addition of lipid has no effect on the fluorescence emission or circular dichroism of glucagon. Thus this hormone can interact with dimyristoyl glycerophosphocholine and this interaction is stronger below the phase transition temperature than above it.     

A fluorescence spectroscopy study on the interactions of the TAT-PTD peptide with model lipid membranes

Protein-transduction domains (PTDs) have been shown to translocate into and through the living cells in a rapid manner by an as yet unknown mechanism. Regardless of the mechanism of translocation, the first necessary step must be binding of the PTD peptide to the surface of the lipid membrane. We used fluorescence spectroscopy to study the interaction between PTD of the HIV-1 Tat protein (TAT-PTD; residues 47-60 of Tat, fluorescently labeled with tryptophan) and the lipid bilayer labeled with various fluorescence membrane probes. The TAT-PTD tryptophan exhibited a decrease in fluorescence intensity and an increase in anisotropy upon interaction with lipid bilayers. The fluorescence changes were linearly proportional to the density of negative charge in the membrane. Kinetic analysis of the interaction showed two apparent dissociation constants. The value of one dissociation constant (Kd1 = 2.6 +/- 0.6 microM), which accounted for 24% of the interaction, was found to be independent of the negative charge density, suggesting its nonelectrostatic nature. The value of the second dissociation constant (Kd2), which accounted for 76% of the interaction, decreased linearly from 610 +/- 150 to 130 +/- 30 microM with an increase in negative charge density from 0 to 25 mol %, suggesting this interaction is electrostatic in nature. Even though the binding was predominantly electrostatic, it could not be reversed by high salt, indicating the presence of a second, irreversible, step in the interaction with lipid. When TAT-PTD was bound to lipid vesicles labeled with 1-(4-trimethylammoniumphenyl)-6-phenyl-1,3,5-hexatriene (TMA-DPH), fluorescence resonance energy transfer between the tryptophan and the probe occurred at a distance of 3.4 nm. No change in fluorescence anisotropy of either TMA-DPH or DPH was observed upon the interaction with TAT-PTD, indicating no significant disruption or perturbation of the lipid bilayer by the peptide. TAT-PTD did not cause dissipation of membrane potential (165 mV, negative inside). Inclusion of 3% pyrene-labeled phosphatidylglycerol (pyrene-PG) in the membrane revealed that TAT-PTD preferentially bound to the membrane in the liquid state. We conclude that membrane fluidity is an important physicochemical parameter, which may regulate binding of TAT-PTD to the membrane.     

Features of the structure of catalytic subunits of toxins, inhibiting protein synthesis. I. The effect of pH and interaction with the B-chain of ricin

A comparative study of gelonin and A-chains of ricin, mistletoe lectin I and diphtheria toxin was undertaken. The effect of pH was studied on: a) the conformation of the proteins under study using intrinsic fluorescence; b) interaction of these proteins with ricin B-chain using gel-filtration. Structural stability of the proteins was assessed according to denaturing action of guanidine hydrochloride and temperature, and localization of tryptophan residues was determined using fluorescence quenching by I-, Cs+ and acrylamide. All investigated proteins were shown to undergo the conformational changes when a environment became acidic. In comparison with an intact protein--gelonin, the A-chains of ricin, a mistletoe lectin and a diphtheria toxin are less stable. At pH less than 5.0 tryptophan residues became more accessible to quencher and a positive charge of the surrounding area increases (in the case of gelonin it is negatively charged). No reliable interaction of a ricin B-chain with both gelonin and A-chain of diphtheria toxin was observed. The interaction of a ricin B-chain with a A-chain of mistletoe lectin I is weaker than that with ricin A-chain and is practically pH-independent.     

The role of charge and hydrophobicity in peptide-lipid interaction: a comparative study based on tryptophan fluorescence measurements combined with the use of aqueous and hydrophobic quenchers

The interaction of interrelated model peptides with model membranes has been studied by techniques based on tryptophan fluorescence. The peptides used are derivatives of the sequence H-Ala-Met-Leu-Trp-Ala-OH, which was designed for this purpose. Several modifications yielded a set of 13 penta- and hexapeptides varying in net charge, hydrophobicity, charge distribution, and the intramolecular position of the tryptophan residue with respect to the charge(s). The affinity of these peptides for small unilamellar vesicles (SUV) consisting of zwitterionic egg phosphatidylcholine (eggPC) and negatively charged beef heart cardiolipin (bhCL) has been investigated in a comparative way. The criteria for affinity comprise (1) intrinsic fluorescence changes upon titration of the peptides with the lipid vesicles, (2) reduced accessibility of the peptides to aqueous quenchers of tryptophan fluorescence (I- and acrylamide) in the presence of lipid, and (3) exposure to membrane-incorporated fluorescence quenchers, brominated phosphatidylcholines (BrPC). Application of BrPC brominated at different positions along the acyl chains provided information on the membrane topology of the peptides. With respect to the extent of affinity for zwitterionic membranes, the overall hydrophobicity of the peptides is the main determinant. A comparison of the affinity for PC of equally hydrophobic peptides carrying either a single positive or negative charge reveals preferential interaction of the cationic peptide. Both hydrophobic and electrostatic interactions determine the affinity of positively charged mono- and divalent peptides for CL vesicles. The distribution of the charged moieties in divalent positively charged peptides, either both at one end of the molecule or one at each end, has little influence on the affinity of these peptides for CL but does affect the extent of exposure to BrPC. Upon decreasing the surface charge density of the vesicles by diluting CL with increasing amounts of PC, both types of peptides show different behavior. The position of the tryptophan relative to the charged moiety in the peptide molecule is shown to affect the fluorescent properties upon interaction with vesicles. Concerning the membrane topology, all peptides adopt a localization near the membrane surface, with the neutral peptides inserting slightly deeper into the bilayer than the charged peptides. The results allow a comparative analysis of the factors determining the extents and modes of lipid-model peptide interaction; in addition, the validity of the methods applied is discussed.     

Venom exonuclease. IV. Intrinsic fluorescence of the exonuclease from Crotalus adamanteus venom

The intrinsic fluorescence of the exonuclease isolated from Crotalus adamanteus venom, was studied. The position of its maximum at 335 nm and half-width of the emission band 55 nm (lambda exc. 295 nm) suggested the existence of at least two types of tryptophan residues in the enzyme molecule. Differential analysis of the fluorescence spectra obtained by excitation at 280 and 295 nm revealed about 12.5% contribution of the tyrosine fluorescence in the overall emission excited at 280 nm. The environment of the tryptophan residues in the exonuclease was studied by quenching of their fluorescence with various ionic (NO3-, NO2-, I-, Br- and Cs+) and non-ionic agents (acrylamide, chloroform-methanol). On this basis, fractions of inner (non-polar) and surface tryptophan residues located in charged and neutral regions of the enzyme molecule were evaluated. More than half of the residues (60%) was found in the inner part of the exonuclease while most of its surface tryptophans--in a neutral region(s).     

Membrane binding of MARCKS-related protein studied by tryptophan fluorescence spectroscopy

MARCKS-related protein (MRP) is a peripheral membrane protein whose binding to membranes is mediated by the N-terminal myristoyl moiety and a central, highly basic effector domain. MRP mediates cross-talk between protein kinase C and calmodulin and is thought to link the actin cytoskeleton to the plasma membrane. Since MRP contains no tryptophan residues, we mutated a phenylalanine in the effector domain to tryptophan (MRP F93W) and used fluorescence spectroscopy to monitor binding of the protein to phospholipid vesicles. We report in detail the evaluation procedure necessary to extract quantitative information from the raw data. The spectra of MRP F93W obtained in the presence of increasing amounts of lipid crossed at an isosbestic point, indicating a simple transition between two states: free and membrane-bound protein. The change in fluorescence toward values typical of a more hydrophobic environment was used to quantify membrane binding. The partition coefficient agreed well with values obtained previously by other methods. To study the interaction of the N-terminus of MRP with membranes, a tryptophan residue was also introduced at position 4 (MRP S4W). Our data suggest that only the myristoylated N-terminus interacted with liposomes. These results demonstrate the versatility of site-directed incorporation of tryptophan residues to study protein-membrane interactions.