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.     

Binding of Saccharides to Abrin-b Isolated from Abrus precatorius Seeds

The nature of the binding of saccharides to arbin-b, a toxic lectin isolated from Abrus precatorius seeds, was studied by equilibrium dialysis and fluorescence spectroscopy. Equilibrium dialysis data indicate that abrin-b has two saccharide-binding sites, a high affinity site (HA-site) and a low affinity site (LA-site), to which both galactopyranosides and N-acetylgalactosamine can bind. With excitation at 290 nm, abrin-b displayed a fluorescence spectrum with an emission maximum at 345 nm. Upon binding with specific saccharides, this spectrum shifted to a wavelength shorter by 5 nm, suggesting that saccharides bind to abrin-b in such a manner as to induce a change in the environment of the tryptophan residue or residues at or near the respective binding sites. From the variation of fluorescence at 320 nm with saccharide concentrations, the association constants for binding of saccharides to the respective sites were measured. The results suggest that the HA-site has a subsite favorable for saccharides having β-1,4 linked galactopyranoside at the non-reducing end like lactose in addition to the galactose-recognition site, while the LA-site may not have such a subsite.     

States of tryptophan residues in castor bean hemagglutinin: the perturbing effects of solvents on tryptophans in hemagglutinin and its complexes as analyzed by UV-difference spectroscopy

The states of tryptophan residues in castor bean hemagglutinin (CBH) were analyzed by solvent perturbation studies employing ultraviolet difference spectroscopy. Eight out of 22 tryptophan residues in CBH were exposed to ethylene glycol and glycerol, suggesting that the remaining 14 tryptophan residues are buried in the interior of the CBH molecule. The fraction of tryptophan residues accessible to the perturbant decreased with increase in the molecular size of the perturbant, and only 2 tryptophan residues were exposed to polyethylene glycol 600. Upon binding with raffinose, 2 tryptophan residues were shielded from the perturbing effect of the solvent, and binding of lactose reduced the number of tryptophan residues accessible to the perturbant by 1 mol per mol of protein. Binding of galactose, however, did not change the accessibility of tryptophan to the perturbant. On the other hand, the accessibility of tyrosine to the perturbant remained unchanged after binding with raffinose and lactose, suggesting that tyrosine is not directly involved in the saccharide binding of CBH. Based on these results, it is proposed that one tryptophan residue at the saccharide-binding site on each B-chain of CBH lies on the surface of the protein molecule and is located at a subsite which is accessible to a glucopyranoside moiety in the lactose molecule or a glycopyranosyl-fructofuranosyl moiety in the raffinose molecule, whereas such a residue is not present at the galactopyranoside-recognition site.     

Ultraviolet difference spectroscopic analysis of the saccharide-binding properties of Ricinus communis agglutinin

The nature of the binding of saccharides to Ricinus communis agglutinin was studied by ultraviolet difference spectroscopy. Upon binding of galactose and galactose-containing saccharides, R. communis agglutinin displayed difference spectra with an extreme maximum at 291-293 nm and a smaller maximum at 284-285 nm. Such difference spectra suggest that the environment of a tryptophan residue located at or near the saccharide-binding site of R. communis agglutinin is being changed by an interaction between a tryptophan residue and the bound saccharides. The value of the difference spectra (delta epsilon) increased upon progressive addition of saccharide until the saccharide binding site was saturated with ligand. From the increase in delta epsilon at 291-293 nm, the association constants were obtained for the R. communis agglutinin-saccharide interaction over the temperature range 5-35 degrees C and various pH values. The results clearly demonstrate that the association constants are nearly equal in the range of pH 5-8, but decrease beyond the above pH range and with elevation of temperature. From the thermodynamic parameters for the binding of various saccharides to R. communis agglutinin, we suggest that there exists a subsite structure in the saccharide-binding site of the R. communis agglutinin molecule.     

Isoamylamine as the Possible Neuroactive Metabolite of l-Leucine

The states of tryptophan residues in Abrus precatorius agglutinin (APA) were analyzed by chemical modification and solvent perturbation UV-difference spectroscopy. The number of tryptophan residues available for N-bromosuccinimide (NBS) oxidation increased with lowering pH, and 20 out of the 24 tryptophans in APA were modified at pH 3.0, while 2 tryptophans were eventually oxidized at pH 5.0. Modification of tryptophan greatly decreased the binding of APA with saccharides, and only 4% of the hemagglutinating activity was retained after modification of 4 tryptophan residues/molecule. When the modification was done in the presence of lactose or galactose, 2 tryptophan residues/molecule remained unmodified with a retention of a fairly high hemagglutinating activity. The data from solvent perturbation UV-difference spectroscopy indicated that 6 tryptophans were on the surface of the APA molecule, and 4 tryptophan residues/molecule were shielded from the perturbing effect of the solvent upon binding with lactose.

Based on these results, we proposed that in the saccharide-binding site on each B-chain of APA there exists one tryptophan residue directly involved in saccharide binding, and near the binding site there is another tryptophan residue whose state is also changeable upon binding with saccharide.     

Chemical Modification of Tryptophan Residues in Castor Bean Hemagglutinin

Modification of tryptophan residues in castor bean hemagglutinin (CBH) with N-bromosuccinimide (NBS) was investigated in detail. Tryptophan residues accessible to NBS increased with lowering pH and six tryptophan residues/mol were oxidized at pH 3.0, while two tryptophan residues/mol were oxidized at pH 5.0. From the pH-dependence curve for tryptophan oxidation, we suggest that the extent of modification of tryptophan in CBH is influenced by an ionizable group with pK_a = 3.6. The saccharide-binding activity was decreased greatly by modification of tryptophan concomitantly with a loss of fluorescence. A loss of the saccharide-binding activity was found to be principally due to the modification of two tryptophan residues/mol located on the surface of the protein molecule. In the presence of raffinose, two tryptophan residues/mol remained unmodified with retention of fairly high saccharide-binding activity. The results suggest that one tryptophan residue is involved in each saccharide-binding site on each B-chain of CBH.     

Identification of the Tryptophan Residue Located at the Saccharide Binding Site of Castor Bean Hemagglutinin

The tryptophan residue present at the saccharide-binding site of castor bean hemagglutinin (CBH) was identified. A peptide containing a modified tryptophan residue was isolated from the tryptic digest of S-car boxy methylated B-chain obtained from an inactive derivative of CBH (2-Oxa-CBH), in which two tryptophan residues/mol were oxidized with Af-bromosuccinimide, by gel filtration on a Sephadex G-50 followed by high performance liquid chromatography. Analytical data for the isolated peptide indicated that the tryptophan residue at position 131 on the B-chain was modified in 2-Oxa-CBH.

From these and earlier results, it is suggested that the tryptophan residue at 131 on each B-chain is closely associated with the saccharide-binding activity of CBH. The specific role of tryptophan residue at 131 in the saccharide-binding site of CBH is also discussed.     

Ricin D-saccharide interaction as studied by ultraviolet difference spectroscopy

The interaction of ricin D with specific saccharides was investigated by ultraviolet difference spectroscopy. Upon binding to saccharides, ricin D displayed ultraviolet difference spectra with maxima at 280 nm and 288 nm. Such difference spectra suggest that the environment of a tyrosine residue(s) located at or near the saccharide-binding site is changed by the binding of saccharide. In addition to the two positive peaks, a small trough was observed around 300 nm in the complexes with galactose-containing saccharides but not in the complex with N-acetylgalactosamine or galactosamine, suggesting the participation of tryptophan in the binding with galactose-containing saccharides. The magnitude of the difference maxima increased with increasing concentration of saccharides until the binding site was saturated. From the variation of the maximum at 288 nm as a function of saccharide concentration, the association constants were obtained for the binding of saccharides to ricin D at various temperatures and pH's. The saccharide binding of ricin D decreased with increasing temperature and with decreasing pH below pH 6.0. It was suggested that difference maximum at 288 nm observed in the ricin D-saccharide interaction reflects the binding of saccharides to the high-affinity saccharide-binding site of ricin D.     

Evidence for involvement of tryptophan residue in the low-affinity saccharide binding site of ricin D

The nature of the saccharide-binding site of ricin D, which is a galactose- and N-acetylgalactosamine-specific lectin, was studied by chemical modification and spectroscopy. With excitation at 290 nm, ricin D displayed a fluorescence spectrum with a maximum at 335 nm. Upon binding of the specific saccharides, the spectrum shifted to shorter wavelength by 3 nm. However, binding of galactosamine and N-acetylgalactosamine failed to induce such a change in the fluorescence spectrum. The interaction of ricin D with its specific saccharides was analyzed in terms of the variation of the intensity at 320 nm as a function of saccharide concentration. The results indicate that the change in the fluorescence spectrum induced by saccharide binding is attributable to the binding of saccharide to the low-affinity (LA-) binding site of ricin D. The cytoagglutinating activity of ricin D decreased to 2% upon modification of two tryptophan residues/mol with N-bromosuccinimide at pH 4.0, but in the presence of galactose or lactose one tryptophan residue/mol remained unmodified, and a fairly high cytoagglutinating activity was retained. Galactosamine and N-acetylgalactosamine did not show such a protective effect. Spectroscopic analyses indicate that the decrease in the cytoagglutinating activity of ricin D upon tryptophan modification is principally due to the loss of the saccharide binding activity of the LA-binding site. The results suggest that one tryptophan residue is essential for saccharide binding at the LA-binding site, which can bind galactose and lactose but lacks the ability to bind N-acetylgalactosamine and galactosamine.     

Significance of the Tryptophan Residue at the Low Affinity Saccharide-binding Site of Ricin E

Chemical modification of tryptophan residues in ricin E was investigated with regard to saccharide-binding. Two out of ten tryptophan residues in ricin E were modified with N- bromosuccinimide at pH 4.5 in the absence of specific saccharide accompanied by a marked decrease in the cytoagglutinating activity. Such a loss of the cytoagglutinating activity was found to be principally due to the oxidation of one tryptophan residue per B-chain. In the presence of lactose, one tryptophan residue/mol was protected from the modification with retention of a fairly high cytoagglutinating activity. However, G a IN Ac did not show such a protective effect. The binding of lactose to ricin E altered the environment of the tryptophan residue at the low affinity binding site of ricin E, leading to a blue shift of the fluorescence spectrum and an UV-difference spectrum with a maximum at 290 nm and a trough at 300 nm. The ability to generate such spectroscopic changes induced by lactose was retained in the derivative in which one tryptophan residue/mol was oxidized in the presence of lactose, but not in the derivative in which two tryptophan residues/mol were oxidized in the absence of lactose. Based on these results, it is suggested that one of the two surface-localized tryptophan residues is responsible for saccharide binding at the low affinity binding site of ricin E, which can bind lactose but lacks the ability to bind GalNAc.     

Fluorescence quenching of dimeric and monomeric forms of yeast hexokinase (PII): effect of substrate binding steady-state and time-resolved fluorescence studies

Fluorescence quenching studies on the PII isoenzyme of yeast hexokinase have been performed using charged as well as polar uncharged quenchers. In both 'open' (i.e. in the absence of glucose) and 'closed' (i.e. in the presence of glucose) forms of the enzyme, bimolecular quenching rate constant (kq) for acrylamide is significantly larger than that of KI, indicating that all the tryptophans are not fully exposed to the solvent. Overall accessibility of tryptophans towards KI was greater in the presence of glucose than in the absence of glucose. At high ionic strength, the value of bimolecular quenching rate constant (kq) for KI did not change suggesting that the average environment of the accessible tryptophan residue(s) is almost neutral. Quenching by KI is dynamic in nature. Accessibility of tryptophans towards acrylamide at concentration > or = 0.2 M was more in the 'open' form of the enzyme than that observed in the 'closed' form whereas at concentration < or = 0.2 M no significant difference in the extent of quenching was observed. It is reasonable to conclude that glucose induced conformational change leads some tryptophan residue(s) to be more exposed and at the same time some tryptophan residue(s) in the hydrophobic region become more buried. Dimeric and monomeric forms of the enzyme behave similarly towards the quenching by acrylamide. In the unfolded state, the accessibility of tryptophans was considerably higher for both the quenchers. Temperature dependent study and the fluorescence lifetime data indicate that the mechanism of quenching by acrylamide is primarily dynamic in nature.     

Binding of saccharides to ricin E isolated from small castor beans

The binding of saccharides to ricin E isolated from small castor beans was studied by equilibrium dialysis and spectroscopy. Equilibrium dialysis data indicate that ricin E has two galactose-binding sites, a high affinity site (HA-site) and a low affinity site (LA-site). The binding of specific saccharides to ricin E induces a shift of the fluorescence spectrum to shorter wavelength by 3 nm and UV-difference spectra with a maximum at 290 nm and a negative intensity around 300 nm. The interaction of ricin E with its specific saccharides was analyzed in terms of the variation of the intensity at 320 nm in the fluorescence spectrum and the magnitude of the negative intensity at 300 nm in the UV-difference spectra as functions of saccharide concentration. The results indicate that these spectroscopic changes are representative of the binding of saccharides to the LA-site, which contains a tryptophan residue. By comparing the association constants of saccharides for ricin E with those for ricin D, isolated from the large castor beans, it was found that the HA of ricin E binds saccharides with an affinity of less than one-half that of ricin D, while the saccharide-binding abilities of the LA-site of the two ricins were about the same.     

Identification of the tryptophan residue located at the low-affinity saccharide binding site of ricin D

The saccharide binding ability of the low affinity (LA-) binding site of ricin D was abrogated by N-bromosuccinimide (NBS)-oxidation, while in the presence of lactose the number of tryptophan residues eventually oxidized decreased by 1 mol/mol and the saccharide binding ability was retained (Hatakeyama et al., (1986) J. Biochem. 99, 1049-1056). Based on these findings, the tryptophan residue located at the LA-binding site of ricin D was identified. Two derivatives of ricin D which were modified with NBS in the presence and absence of lactose were separated into their constituent polypeptide chains (A- and B-chains), respectively. The modified tryptophan residue or residues was/were found to be contained in the B-chain, but not in the A-chain. From lysylendopeptidase and chymotryptic digests, peptides containing oxidized tryptophan residues were isolated by gel filtration on Bio-Gel P-30 and HPLC. Analysis of the peptides containing oxidized tryptophan revealed that three tryptophan residues at positions 37, 93, and 160 on the B-chain were oxidized in the inactive derivative of ricin D, in which the saccharide binding ability of the LA-binding site was abrogated by NBS-oxidation. On the other hand, the modified residues were determined to be tryptophans at positions 93 and 160 in the active derivative of ricin D which was modified in the presence of lactose, indicating that upon binding with lactose, the tryptophan residue at position 37 of the B-chain was protected from NBS-oxidation. From these results, it is suggested that tryptophan at position 37 on the B-chain is the essential residue for saccharide binding at the LA-binding site of ricin D.     

Simple Synthesis of (R)-5-Hexadecanolide

Chemical modification of tryptophan residues in abrin-a with N-bromosuccinimide (NBS) was studied with regard to saccharide-binding. The number of tryptophan residues available for NBS oxidation increased with lowering pH, and 11 out of the 13 tryptophan residues in abrin-a were eventually modified with NBS at pH 4.0, while 6 tryptophan residues were modified at pH 6.0 in the absence of specific saccharides. Modification of tryptophan residues at pH 6.0 greatly decreased the saccharide-binding ability of abrin-a, and only 2% of the hemagglutinating activity was retained after modification of 3 residues/mol. When the modification was done in the presence of lactose or galactose, 1 out of 3 residues/mol remained unmodified with a retention of a fairly high hemagglutinating activity. However, GalNAc did not show such a protective effect. NBS-oxidation led to a great loss of the fluorescence of abrin-a, and after modification of 3 tryptophan residues/mol, the fluorescence intensity at 345 nm was only 38% of that of the unmodified abrin-a. The binding of lactose to abrin-a altered the environment of the tryptophan residue at the saccharide-binding site of abrin-a, leading to a blue shift of the fluorescence spectrum. The ability to generate such fluorescence spectroscopic changes induced by lactose-binding was retained in the derivative in which 2 tryptophan residues/mol were oxidized in the presence of lactose, but not in the derivative in which 3 tryptophan residues/mol were oxidized in the absence of lactose. Importance of the tryptophan residue(s) in the saccharide-binding of abrin-a is suggested.     

Biotin binding changes the conformation and decreases tryptophan accessibility of streptavidin

Biotin binding reduces the tryptophan fluorescence emissions of streptavidin by 39%, blue shifts the emission peak from 333 to 329 nm, and reduces the bandwidth at half height from 53 to 46 nm. The biotin-induced emission difference spectrum resembles that of a moderately polar tryptophan. Streptavidin fluorescence can be described by two lifetime classes: 2.6 nsec (34%) and 1.3 nsec (66%). With biotin bound, lifetimes are 1.3 nsec (26%) and 0.8 nsec (74%). Biotin binding reduces the average fluorescence lifetime from 1.54 to 0.88 nsec. Biotin does not quench the fluorescence of indoles. The fluorescence changes are consistent with biotin binding causing a conformational change which moves tryptophans into proximity to portions of streptavidin which reduce the quantum yield and lifetimes. Fluorescence quenching by acrylamide revealed two classes of fluorophores. Analysis indicated a shielded component comprising 20–28% of the initial fluorescence with (K_SV+V)0.55 M^–1. The more accessible component has a predominance of static quenching. Measurements of fluorescence lifetimes at different acrylamide concentrations confirmed the strong static quenching. Since static quenching could be due to acrylamide binding to streptavidin, a dye displacement assay for acrylamide binding was constructed. Acrylamide does bind to streptavidin (Ka=5 M^–1), and probably binds within the biotin-binding site. In the absence of biotin, none of streptavidin's fluorescence is particularly accessible to iodide. In the presence of biotin, iodide neither quenches fluorescence nor alters emission spectra, and acrylamide access is dramatically reduced. We propose that the three tryptophans which always line the biotin site are sufficiently close to the surface of the binding site to be quenched by bound acrylamide. These tryptophans are shielded from iodide, most probably due to steric or ionic hindrances against diffusion into the binding site. Most of the shielding conferred by biotin binding can be attributed to the direct shielding of these residues and of a fourth tryptophan which moves into the binding site when biotin binds, as shown by X-ray studies (Weberet al., 1989).     

Detection, characterization, and quenching of the intrinsic fluorescence of bovine heart cytochrome c oxidase

The intrinsic fluorescence of lauryl maltoside solubilized bovine heart cytochrome c oxidase has been determined to arise from tryptophan residues of the oxidase complex. The magnitude of the fluorescence is approximately 34% of that from n-acetyltryptophanamide (NATA). This level of fluorescence is consistent with an average heme to tryptophan distance of 30 A. The majority of the fluorescent tryptophan residues are in a hydrophobic environment as indicated by the fluorescence emission maximum at 328 nm and the differing effectiveness of the quenching agents: Cs+, I-, and acrylamide. Cesium was ineffective up to a concentration of 0.7 M, whereas quenching by the other surface quenching agent, iodide, was complex. Below 0.2 M, KI was ineffective whereas between 0.2 and 0.7 M 15% of the tryptophan fluorescence was found to be accessible to iodide. This pattern indicates that protein structural changes were induced by iodide and may be related to the chaotropic character of KI. Acrylamide was moderately effective as a quenching agent of the oxidase fluorescence with a Stern-Volmer constant of 2 M-1 compared with acrylamide quenching of NATA and the water-soluble enzyme aldolase having Stern-Volmer constants of 12 M-1 and 0.3 M-1, respectively. There was no effect of cytochrome c on the tryptophan emission intensity from cytochrome c oxidase under conditions where the two proteins form a tight, 1:1 complex, implying that the tryptophan residues near the cytochrome c binding site are already quenched by energy transfer to the homes of the oxidase. The lauryl maltoside concentration used to solubilize the enzyme did not affect the fluorescence of NATA.(ABSTRACT TRUNCATED AT 250 WORDS)     

Nonexistence of Exo-cellobiohydrolase (CBH) in the Cellulase System of Trichoderma viride

Chemical modification of histidine residues in ricin E was studied with regard to saccharide binding. The analytical data indicate that 6 out of 7 histidine residues in ricin E are eventually modified with diethylpyrocarbonate (DEP) at pH 6.0 and 25°C in the absence of specific saccharides. Modification of histidine residues greatly decreased the cytoagglutinating activity of ricin E, and only 10% of the residual activity was found after modification of 6 histidine residues/mol. The data of affinity chromatography using lactamyl- and galactosamine-cellulofine columns suggest that modification of histidine residues does not have much effect on the binding ability at the low affinity saccharide-binding site of ricin E but abolishes the binding ability at the high affinity saccharide-binding site. In the presence of lactose, one histidine residue/mol was protected from the DEP modification with retention of a fairly high cytoagglutinating activity. Such a protective effect was also observed for specific saccharides such as galactose and A^-acetylgalactosamine, but not for glucose, a non-specific saccharide. On treatment with hydroxylamine, the modified ricin E restored 67 % of the cytoagglutinating activity. Based on these findings, it is suggested that in the high affinity saccharide- binding site of ricin E there exists one histidine residue responsible for saccharide binding.     

Cofactor and DNA interactions in EcoRI DNA methyltransferase. Fluorescence spectroscopy and phenylalanine replacement for tryptophan 183.

EcoRI DNA methyltransferase contains tryptophans at positions 183 and 225. Tryptophan 225 is adjacent to residues previously implicated in S-adenosylmethionine (AdoMet) binding and to cysteine 223, previously shown to be the site of N-ethyl maleimide-mediated inactivation of the enzyme (Reich, N. O., and Everett, E. (1990) J. Biol. Chem. 265, 8929-8934; Everett, E. A., Falick, A. M., and Reich, N. O. (1990) J. Biol. Chem. 265, 17713-17719). The fluorescence spectra of the wild-type enzyme is centered at 338 nm indicating partial tryptophan solvent accessibility. Substitution of tryptophan 183 with phenylalanine results in a 45% drop in fluorescence intensity, but no shift in lambda max. DNA binding to the wild-type methyltransferase caused an increase in the fluorescence intensity, while binding to the tryptophan 183 mutant had a quenching effect, suggesting that DNA binding induces a conformational change near both tryptophans. Binding of AdoMet and various AdoMet analogs to the wild-type methyltransferase results in no change in the fluorescence spectrum when excitation occurs at 295 nm, suggesting that no conformational change occurs, and AdoMet does not interact with either tryptophan. In contrast, quenching was observed when excitation occurred at 280 nm, suggesting that AdoMet and its analogs may be quenching tyrosine to tryptophan energy transfer. Protein-ligand complexes were titrated with acrylamide, and the data also implicate conformational changes upon DNA binding but not upon AdoMet binding, consistent with previous limited proteolysis results (Reich, N. O., Maegley, K. A., Shoemaker, D.D., and Everett, E. (1991) Biochemistry 30, 2940-2946).     

Intrinsic tryptophan fluorescence of Schizosaccharomyces pombe mitochondrial F1-ATPase. A powerful probe for phosphate and nucleotide interactions

Mitochondrial F1 from the yeast Schizosaccharomyces pombe, in contrast to the mammalian enzyme, exhibits a characteristic intrinsic tryptophan fluorescence with a maximal excitation at 291 nm and a maximal emission at 332 nm. Low values of Stern-Volmer quenching constants, 4.0 M-1 or 1.8 M-1, respectively, in the presence of either acrylamide or iodide, indicate that tryptophans are mainly buried inside the native enzyme. Upon subunit dissociation and unfolding by 6 M guanidine hydrochloride (Gdn.HCl), the maximal emission is shifted to 354 nm, a value very similar to that obtained with N-acetyltryptophanamide, a solute-tryptophan model compound. The tryptophan content of each isolated subunit has been estimated by fluorescence titration in the presence of Gdn.HCl with free tryptophan as a standard. Two tryptophans and one tryptophan are found respectively in the alpha and epsilon subunits, whereas none is detected in the beta, gamma, and delta subunits. These subunit contents are consistent with the total of seven tryptophans estimated for native F1 with alpha 3 beta 3 gamma 1 delta 1 epsilon 1 stoichiometry. The maximal emission of the isolated epsilon subunit is markedly blue-shifted to 310-312 nm by interaction with the isolated delta subunit, which suggests that the epsilon subunit tryptophan might be a very minor contributor to the native F1 fluorescence measured at 332 nm. This fluorescence is very sensitive to phosphate, which produces a marked blue shift indicative of tryptophans in a more hydrophobic environment. On the other hand, ADP and ATP quench the maximal emission at 332 nm, lower tryptophan accessibility to acrylamide, and reveal tryptophan heterogeneity.     

Ultraviolet difference spectroscopic studies on the saccharide-binding properties of Abrus precatorius agglutinin

The nature of the binding of specific saccharides to Abrus precatorius agglutinin (APA) was studied by ultraviolet difference spectroscopy. Upon binding of saccharides, APA displayed difference spectra with maxima at 291-292 nm and 284-285 nm. Such spectra suggest that the state of the tryptophan residue closely associated with the saccharide-binding activity of APA is perturbed by the binding of a saccharide. The difference spectra value (delta epsilon) increased with increasing saccharide concentration. From the increase in delta epsilon at 291-292 nm, the association constant (Ka) was obtained for the binding of individual saccharides to APA. Lactose bound to APA with the highest affinity among the saccharides examined and its Ka value (8.3 X 10(3) M-1 at pH 7.0 and 25 degrees C) was approximately four times as large as that of galactose (2.2 X 10(3) M-1). Raffinose and methyl beta-galactopyranoside showed larger association constants than galactose. Galactosamine, N-acetylgalactosamine and 2-deoxy galactose were found to bind with APA with fairly low affinity. The shape of the lactose-induced difference spectrum changed with pH and the spectrum in the acidic region showed characteristic broadening of the difference maximum peaks. The affinity of lactose to APA was nearly equal in the range of pH 6-8, but decreased outside this pH region and with increasing temperature.