Preferred Conformers and Photochemical (λ > 200 nm) Reactivity of Serine and 3,3-Dideutero-Serine In the Neutral Form

A systematic investigation of the conformational potential energy surface of neutral serine [HOCH2CHNH2COOH] and 3,3-dideutero-serine [HOCD2CHNH2COOH] was undertaken, revealing the existence of 61 different minima. The structures and vibrational spectra of the most stable conformers, which were estimated to have relative energies within 7 kJ mol(-1) and account for ca. 93% of the total conformational population at room temperature, were calculated at both the MP2 and DFT/BLYP levels of theory with the 6-311++G(d,p) basis-set and used to interpret the spectroscopic data obtained for the compounds isolated in low-temperature inert matrixes. The assignment of the main spectral infrared features observed in the range 4000-400 cm(-1) to the most stable conformers of serine was undertaken. In addition, UV irradiation (lambda > 200 nm) of the matrix-isolated compounds was also performed, leading to decarboxylation, which was found to be strongly dependent on the conformation assumed by the reactant molecule.

Cα−H Bond-Stretching Frequency in Alcohols as a Probe of Hydrogen-Bonding Strength: A Combined Vibrational Spectroscopic and Theoretical Study of n-[1-D]Propanol

The sensitivity of the nu(C)()alpha(-)(H/D) vibrational stretching frequency to hydrogen bonding in alcohols is examined by infrared and Raman spectroscopy, supported by DFT(B3LYP)/6-311++G(d,p) calculations. The model compound studied is (R,S)-n-[1-D]propanol. It is shown that the nu(C)()alpha(-)(H/D) mode can be successfully correlated with the hydrogen-bond strength in a given solvent, provided the O-H group involved in the hydrogen bond is not acting simultaneously as a hydrogen-bond donor and acceptor. In addition, a detailed analysis of the spectroscopic features observed in both the nu(O)(-)(H) and nu(C)()alpha(-)(H/D) spectral regions of the spectra of n-propanol and (R,S)-n-[1-D]propanol, in a series of different experimental conditions, which include the matrix-isolated compound (in argon matrix), pure liquid and low-temperature glassy states, and solution in different solvents, is undertaken. This permits the contribution of the different conformers of the studied compounds to be assigned to the bands observed in the nu(O)(-)(H) and nu(C)(-)(H) spectral regions.

Probing inhibitors binding to human urokinase crystals by Raman microscopy: implications for compound screening

Inhibition of urokinase activity represents a promising target for antimetastatic therapy for several types of tumor. The present study sets out to investigate the potential of Raman spectroscopy for defining the molecular details of inhibitor binding to this enzyme, with emphasis on single crystal studies. It is demonstrated that high quality Raman spectra from a series of five inhibitors bound individually to the active site of human urokinase can be obtained in situ from urokinase single crystals in hanging drops by using a Raman microscope. After recording the spectrum of the free crystal, a solution of inhibitor containing an amidine functional group on a naphthalene ring was added, and the spectrum of the crystal-inhibitor complex was obtained. The resulting difference Raman spectrum contained only vibrational modes due to bound inhibitor, originating from the protonated group, i.e., the amidinium moiety, as well as naphthalene ring modes and features from other functionalities that made up each inhibitor. The identification of the amidinium modes was placed on a quantitative basis by experimental and theoretical work on naphthamidine compounds. For the protonated group, -C-(NH2)(2)(+), the symmetric stretch occurs near 1520 cm(-1), and a less intense antisymmetric mode appears in the Raman spectra near 1680 cm(-1). The presence of vibrational modes near 1520 cm(-1) in each of the Raman difference spectra of the five complexes examined unambiguously identifies the protonated form of the amidinium group in the active site. Several advantages were found for single crystal experiments over solution studies of inhibitor-enzyme complexes, and these are discussed. The use of single crystals permits competitive binding experiments that cannot be undertaken in solution in any kind of homogeneous assay format. The Raman difference spectrum for a single crystal that had been exposed to equimolar amounts of all five inhibitors in the hanging drop showed only the Raman signature of the compound with the lowest K(i). These findings suggest that the Raman approach may offer a route in the screening of compounds in drug design applications as well as an adjunct to crystallographic analysis.

Comparing protein-ligand interactions in solution and single crystals by Raman spectroscopy

By using a Raman microscope, we show that it is possible to probe the conformational states in protein crystals and crystal fragments under growth conditions (in hanging drops). The flavin cofactor in the enzyme para-hydroxybenzoate hydroxylase can assume two conformations: buried in the protein matrix ("in") or essentially solvent-exposed ("out"). By using Raman difference spectroscopy, we previously have identified characteristic flavin marker bands for the in and out conformers in the solution phase. Now we show that the flavin Raman bands can be used to probe these conformational states in crystals, permitting a comparison between solution and crystal environments. The in or out marker bands are similar for the respective conformers in the crystal and in solution; however, significant differences do exist, showing that the environments for the flavin's isoalloxazine ring are not identical in the two phases. Moreover, the Raman-band widths of the flavin modes are narrower for both in and out conformers in the crystals, indicating that the flavin exists in a more limited range of closely related conformational states in the crystal than in solution. In general, the ability to compare detailed Raman data for complexes in crystals and solution provides a means of bridging crystallographic and solution studies.

Crystallization and preliminary X-ray analysis of the 12S central subunit of transcarboxylase from Propionibacterium shermanii

The hexameric 12S central subunit of transcarboxylase has been crystallized in both free and substrate-bound forms. The apo crystals belong to the cubic space group P4(2)32, with unit-cell parameters a = b = c = 188.5 A, and diffract to 3.5 A resolution. Crystals of two substrate-bound complexes, 12S with methylmalonyl CoA and 12S with malonyl CoA, are isomorphous and belong to space group C2, with unit-cell parameters a = 115.5, b = 201.4, c = 146.9 A, beta = 102.7 degrees. These crystals diffract to 1.9 A resolution with synchrotron radiation. Two useful heavy-atom phasing derivatives of methylmalonyl CoA-bound crystals have been obtained by co-crystallization or crystal soaking.

Raman spectroscopy of uracil DNA glycosylase-DNA complexes: insights into DNA damage recognition and catalysis

Using off-resonance Raman spectroscopy, we have examined each complex along the catalytic pathway of the DNA repair enzyme uracil DNA glycosylase (UDG). The binding of undamaged DNA to UDG results in decreased intensity of the DNA Raman bands, which can be attributed to an increased level of base stacking, with little perturbation in the vibrational modes of the DNA backbone. A specific complex between UDG and duplex DNA containing 2'-beta-fluorodeoxyuridine shows similar increases in the level of DNA base stacking, but also a substrate-directed conformational change in UDG that is not observed with undamaged DNA, consistent with an induced-fit mechanism for damage site recognition. The similar increases in the level of DNA base stacking for the nonspecific and specific complexes suggest a common enzyme-induced distortion in the DNA, potentially DNA bending. The difference spectrum of the extrahelical uracil base in the substrate-analogue complexes reveals only a small electron density reorganization in the uracil ring for the ground state complex, but large 34 cm(-)(1) downshifts in the carbonyl normal modes. Thus, UDG activates the uracil ring in the ground state mainly through H bonds to its C=O groups, without destroying its quasi-aromaticity. This result is at variance with the conclusion from a recent crystal structure, in which the UDG active site significantly distorts the flipped-out pseudouridine analogue such that a change in hybridization at C1 occurs [Parikh, S. S., et al. (2000) Proc. Natl. Acad. Sci. USA 97, 5083]. The Raman vibrational signature of the bound uracil product differs significantly from that of free uracil at neutral pH, and indicates that the uracil is anionic. This is consistent with recent NMR results, which established that the enzyme stabilizes the uracil anion leaving group by 3.4 pK(a) units compared to aqueous solution, contributing significantly to catalysis. These observations are generally not apparent from the high-resolution crystal structures of UDG and its complexes with DNA; thus, Raman spectroscopy can provide unique and valuable insights into the nature of enzyme-DNA interactions.

High resolution solution structure of the 1.3S subunit of transcarboxylase from Propionibacterium shermanii

Transcarboxylase (TC) from Propionibacterium shermanii, a biotin-dependent enzyme, catalyzes the transfer of a carboxyl group from methylmalonyl-CoA to pyruvate to form propionyl-CoA and oxalacetate. Within the multi-subunit enzyme complex, the 1.3S subunit functions as the carboxyl group carrier and also binds the other two subunits to assist in the overall assembly of the enzyme. The 1.3S subunit is a 123 amino acid polypeptide (12.6 kDa) to which biotin is covalently attached at Lys 89. The three-dimensional solution structure of the full-length holo-1.3S subunit of TC has been solved by multidimensional heteronuclear NMR spectroscopy. The C-terminal half of the protein (51-123) is folded into a compact all-beta-domain comprising of two four-stranded antiparallel beta-sheets connected by short loops and turns. The fold exhibits a high 2-fold internal symmetry and is similar to that of the biotin carboxyl carrier protein (BCCP) of acetyl-CoA carboxylase, but lacks an extension that has been termed "protruding thumb" in BCCP. The first 50 residues, which have been shown to be involved in intersubunit interactions in the intact enzyme, appear to be disordered in the isolated 1.3S subunit. The molecular surface of the folded domain has two distinct surfaces: one side is highly charged, while the other comprises mainly hydrophobic, highly conserved residues.

Using Raman spectroscopy to monitor the solvent-exposed and "buried" forms of flavin in p-hydroxybenzoate hydroxylase

X-ray crystallographic studies of several complexes involving FAD bound to p-hydroxybenzoate hydroxylase (PHBH) have revealed that the isoalloxazine ring system of FAD is capable of adopting in two positions on the protein. In one, the "in" form, the ring is surrounded by protein groups and has little contact with solvent; in the second, "out" form, the ring is largely solvent exposed. Using Raman difference spectroscopy, it has been possible to obtain Raman spectra for the flavin ring in both conformational states for different complexes in solution. The spectra consist of a rich assortment of isoalloxazine ring modes whose normal mode origin can be assigned by using density functional theory and ab initio calculations. Further insight into the sensitivity of these modes to changes in environment is provided by the Raman spectra of lumiflavin in the solid state, in DMSO and in aqueous solution. For the protein complexes, the Raman difference spectra of flavin bound to wt PHBH and wt PHBH plus substrate, p-hydroxybenzoate, provided examples of the "in" conformation. These data are compared to those for flavin bound to wt PHBH plus 2,4-dihydroxybenzoate, where X-ray analysis show that the flavin is "out". There are several spectral regions where characteristic differences exist for flavin in the "in" or "out" conformation, these occur near 1700, 1500, 1410, 1350, 1235, and 1145 cm(-)(1). These spectral features can be used as empirical marker bands to determine the populations of "in" and "out" for any complex of PHBH and to monitor changes in those populations with perturbations to the system, e.g., by changing temperature or pH. Thus, it will now be possible to determine the conformational state of the flavin in PHBH for those complexes that have resisted X-ray crystallographic analysis. Raman difference data are also presented for the Tyr222Phe mutant. The Raman data show that the isoalloxazine ring is predominantly "out" for Tyr222Phe. However, in the presence of the substrate p-hydroxybenzoate there is clear evidence from the Raman marker bands that a mixed population of "in" and "out" exists with the majority being in the "out" state. This is consistent with the conclusions drawn from crystallographic studies on this complex (Gatti, D. L., Palfey, B. A., Lah, M. S., Entsch, B., Massey, V., Ballou, D. P., and Ludwig, M. L. (1994) Science, 266, 110-114).

Molecular structure of 5-methyl thiophene acryloyl ethyl thiolester: a vibrational spectroscopic and density functional theory study

Enzyme-substrate intermediates involving the acyl group 5-methyl thiophene acryloyl (5-MTA) bound to the active site of an enzyme via a sulfur or selenium atom have been characterized by Raman spectroscopy (e.g., J. D. Doran and P. R. Carey, Biochemistry 1996, 35, 12495-12502, and M. J. O'Connor et al., J Amer Chem Soc 1996, 118, 239-240). Raman difference spectra reveal the Raman spectrum of the acyl group in the active site and, in turn, these can be used to probe acyl group conformation and active site forces and interactions. In order to improve the understanding of the relationship between conformational states and vibrational spectra of 5-MTA thiolesters, calculations based on a density functional theory analysis are undertaken for 5-methyl thiophene acryloyl ethyl ester. The calculations provide the precise geometries and energies of rotomers of 5-MTA ethyl thiolester involving rotational isomerism about the C--C single bonds flanking the ethylenic linkage and the S--C bond linking the ethyl group to the sulfur atom. The calculations also provide the vibrational spectrum for each conformer and these predictions are compared with the experimental Raman an IR data for the thiolester in carbon tetrachloride. Modes are identified that can act as conformational markers for isomerism about the C--C and S--C2H5 single bonds. These findings are used to identify the two conformational states giving rise to the Raman spectrum of the 5-MTA-S-enzyme formed by the viral cysteine protease HAV-3C.

Electric fields in active sites: substrate switching from null to strong fields in thiol- and selenol-subtilisins

Although known to be important factors in promoting catalysis, electric field effects in enzyme active sites are difficult to characterize from an experimental standpoint. Among optical probes of electric fields, Raman spectroscopy has the advantage of being able to distinguish electronic ground-state and excited-state effects. Earlier Raman studies on acyl derivatives of cysteine proteases [Doran, J. D., and Carey, P. R. (1996) Biochemistry 35, 12495-502], where the acyl group has extensive pi-electron conjugation, showed that electric field effects in the active site manifest themselves by polarizing the pi-electrons of the acyl group. Polarization gives rise to large shifts in certain Raman bands, e.g. , the C=C stretching band of the alpha,beta-unsaturated acyl group, and a large red shift in the absorption maximum. It was postulated that a major source of polarization is the alpha-helix dipole that originates from the alpha-helix terminating at the active-site cysteine of the cysteine protease family. In contrast, using the acyl group 5-methylthiophene acryloyl (5-MTA) as an active-site Raman probe, acyl enzymes of thiol- or selenol-subtilisin exhibit no polarization even though the acylating amino acid is at the terminus of an alpha-helix. Quantum mechanical calculations on 5-MTA ethyl thiol and selenol ethyl esters allowed us to identify the conformational states of these molecules along with their corresponding vibrational signatures. The Raman spectra of 5-MTA thiol and selenol subtilisins both showed that the acyl group binds in a single conformation in the active site that is s-trans about the =C-C=O single bond. Moreover, the positions of the C=C stretching bands show that the acyl group is not experiencing polarization. However, the release of steric constraints in the active site by mutagenesis, by creating the N155G form of selenol-subtilisin and the P225A form of thiol-subtilisin, results in the appearance of a second conformer in the active sites that is s-cis about the =C-C=O bond. The Raman signature of this second conformer indicates that it is strongly polarized with a permanent dipole being set up through the acyl group's pi-electron chain. Molecular modeling for 5-MTA in the active sites of selenol-subtilisin and N155G selenol-subtilisin confirms the findings from Raman spectroscopic studies and identifies the active-site features that give rise to polarization. The determinants of polarization appear to be strong electron pull at the acyl carbonyl group by a combination of hydrogen bonds and the field at the N-terminus of the alpha-helix and electron push from a negatively charged group placed at the opposite end of the chromophore.

Product catalyzes the deamidation of D145N dehalogenase to produce the wild-type enzyme

Aspartate 145 plays an essential role in the active site of 4-chlorobenzoyl-CoA dehalogenase, forming a transient covalent link at the 4-position of the benzoate during the conversion of the substrate to 4-hydroxybenzoyl-CoA. Replacement of Asp 145 by residues such as alanine or serine results in total inactivation, and stable complexes can be formed with either substrate or product. The Raman spectroscopic characterization of some of the latter is described in the preceding publication (Dong et al.). The present work investigates complexes formed by D145N dehalogenase and substrate or product. Time-resolved absorption and Raman difference spectroscopic data show that these systems evolve rapidly with time. For the substrate complex, initially the absorption and Raman spectra show the signatures of the substrate bound in the active site of the asparagine 145 form of the enzyme but these signatures are accompanied by those for the ionized product. After several minutes these signatures disappear to be replaced with those closely resembling the un-ionized product in the active site of wild-type dehalogenase. Similarly, for the product complex, the absorption and Raman spectra initially show evidence for ionized product in the active site of D145N, but these are rapidly replaced by signatures closely resembling the un-ionized product bound to wild-type enzyme. It is proposed that product bound to the active site of asparagine 145 dehalogenase catalyzes the deamidation of the asparagine side chain to produce the wild-type aspartate 145. For the complexes involving substrate, the asparagine 145 enzyme population contains a small amount of the WT enzyme, formed by spontaneous deamidation, that produces product. In turn, these product molecules catalyze the deamidation of Asn 145 in the major enzyme population. Thus, conversions of substrate to product and of D145N to D145D dehalogenase go on simultaneously. The spontaneous deamidation of asparagine 145 has been characterized by allowing the enzyme to stand at RT in Hepes buffer at pH 7.5. Under these conditions deamidation occurs with a rate constant of 0.0024 h-1. The rate of product-catalyzed deamidation in Hepes buffer at 22 degrees C was measured by stopped-flow kinetics to be 0.024 s-1, 36000 times faster than the spontaneous process. A feature near 1570 cm-1 could be observed in the early Raman spectra of both substrate and product-enzyme complexes. This band is not associated with either substrate or product and is tentatively assigned to an ester-like species formed by the attack of the product's 4-O- group on the carbonyl of asparagine's side chain and the subsequent release of ammonia. A reaction scheme is proposed, incorporating these observations.

Modulating electron density in the bound product, 4-hydroxybenzoyl-CoA, by mutations in 4-chlorobenzoyl-CoA dehalogenase near the 4-hydroxy group

The enzyme 4-chlorobenzoyl-CoA dehalogenase hydrolyzes 4-chlorobenzoyl-CoA (4-CBA-CoA) to 4-hydroxybenzoyl-CoA (4-HBA-CoA). Biochemical and crystallographic studies have identified a critical role for the dehalogenase residue Asp 145 in close proximity to the ligand's 4-hydroxy group in the structure of the product-enzyme complex. In the present study the effects of site selective mutations at Asp 145 on the product complex are explored by Raman spectroscopy. The spectral signatures of the WT-product complex, the large red shift in lambdamax, and the complete reorganization of the benzoyl ring modes in Raman data are absent for the D145E complex. The major spectral perturbations in the WT complex are brought about by strong electron "pull" at the benzoyl carbonyl and electron "push" by the side chain of Asp 145 near the 4-OH group. Acting in concert, these factors polarize the benzoyl's pi-electrons. Since the Raman data show that very strong electron pull occurs at the benzoyl's carbonyl in the D145E complex, it is apparent that the needed electron push near the benzoyl's 4-OH group is missing. Thus, very precise positioning of Asp 145's side chain near the benzoyl's 4-position is needed to bring about the dramatic electron reorganization seen in the WT complex, and this criterion cannot be met by the glutamate side chain with its additional CH2 group. For two other Asp145 mutants D145A and D145S that lack catalytic activity, Raman difference spectroscopic data for product complexes demonstrate the presence of a population of ionized product (i.e., 4-O-) in the active sites. The presence of the ionized phenolate form explains the observation that these complexes have highly red-shifted absorbance maxima with lambdamaxs near 400 nm. For the WT complex only the 4-OH form is seen, ionization being energetically expensive with the presence of the proximal negative charge on the Asp 145 side chain. Semiquantitative estimates of the pKa for the bound product in D145S and D145A indicate that this ionization lies in the pH 6.5-7.0 range. This is approximately 2 pH units below the pKa for the free product. The Raman spectrum of 4-dimethylaminobenzoyl-CoA undergoes major changes upon binding to dehalogenase. The bound form has two features near 1562 and 1529 cm-1 and therefore closely resembles the spectrum of product bound to wild-type enzyme, which underlines the quinonoid nature in these complexes. The use of a newly developed Raman system allowed us to obtain normal (nonresonance) Raman data for the dehalogenase complexes in the 100-300 microM range and heralds an important advance in the application of Raman spectroscopy to dilute solutions of macromolecules.

Structural characterization of the entire 1.3S subunit of transcarboxylase from Propionibacterium shermanii

Transcarboxylase (TC) from Propionibacterium shermanii, a biotin-dependent enzyme, catalyzes the transfer of a carboxyl group from methylmalonyl-CoA to pyruvate in two partial reactions. Within the multisubunit enzyme complex, the 1.3S subunit functions as the carboxyl group carrier. The 1.3S is a 123-amino acid polypeptide (12.6 kDa), to which biotin is covalently attached at Lys 89. We have expressed 1.3S in Escherichia coli with uniform 15N labeling. The backbone structure and dynamics of the protein have been characterized in aqueous solution by three-dimensional heteronuclear nuclear magnetic resonance (NMR) spectroscopy. The secondary structure elements in the protein were identified based on NOE information, secondary chemical shifts, homonuclear 3J(HNHalpha) coupling constants, and amide proton exchange data. The protein contains a predominantly disordered N-terminal half, while the C-terminal half is folded into a compact domain comprising eight beta-strands connected by short loops and turns. The topology of the C-terminal domain is consistent with the fold found in both carboxyl carrier and lipoyl domains, to which this domain has approximately 26-30% sequence similarity.

Scan-rate dependence in protein calorimetry: the reversible transitions of Bacillus circulans xylanase and a disulfide-bridge mutant

The stabilities of Bacillus circulans xylanase and a disulfide-bridge-containing mutant (S100C/N148C) were investigated by differential scanning calorimetry (DSC) and thermal inactivation kinetics. The thermal denaturation of both proteins was found to be irreversible, and the apparent transition temperatures showed a considerable dependence upon scanning rate. In the presence of low (nondenaturing) concentrations of urea, calorimetric transitions were observed for both proteins in the second heating cycle, indicating reversible denaturation occurs under those conditions. However, even for these reversible processes, the DSC curves for the wild-type protein showed a scan-rate dependence that was similar to that in the absence of urea. Calorimetric thermograms for the disulfide mutant were significantly less scan-rate dependent in the presence of urea than in the urea-free buffer. The present data show that, just as for irreversible transitions, the apparent transition temperature for the reversible denaturation of proteins can be scan-rate dependent, confirming the prediction of Lepock et al. (Lepock JR, Rithcie KP, Kolios MC, Rodahl AM, Heinz KA, Kruuf J, 1992, Biochemistry 31:12706-12712). The kinetic factors responsible for scan-rate dependence may lead to significant distortions and asymmetry of endotherms, especially at higher scanning rates. This points to the need to check for scan-rate dependence, even in the case of reversible denaturation, before any attempt is made to analyze asymmetric DSC curves by standard thermodynamic procedures. Experiments with the disulfide-bridge-containing mutant indicate that the introduction of the disulfide bond provides additional stabilization of xylanase by changing the rate-limiting step on the thermal denaturation pathway.

Absence of observable biotin-protein interactions in the 1.3S subunit of transcarboxylase: an NMR study

Transcarboxylase (TC) is a biotin-containing enzyme catalyzing the transfer of a carboxyl group from methylmalonyl-CoA to pyruvate to form propionyl-CoA and oxalacetate. The transfer is achieved via carboxylated biotin bound to a 1.3S subunit within the multisubunit enzyme complex. The 1.3S subunit of TC is a 123 amino acid polypeptide, to which biotin is covalently attached at Lys 89. We have overexpressed 1.3S in Escherichia coli and characterized the biotinylated and apo-forms by 1D- and 2D-NMR spectroscopy. To search for protein-biotin interactions, which could modulate the reactivity of the biotin ring on the 1.3S subunit, we have compared the chemical shifts, relaxation parameters, and NH exchange rates of the ureido ring protons of free and 1.3S-bound biotin. These properties are similar for both forms of the biotin. Further, NOE experiments on 1.3S revealed no detectable cross peaks between biotin and the protein. Consistent with these findings, the 2D NMR data for holo- and apo-1.3S are essentially identical indicating little or no changes in conformation between the two forms of the protein. The conclusion that strong protein-biotin interactions do not exist in 1.3S contrasts with the findings for the biotin carboxylase carrier protein from E. coli acetyl-CoA carboxylase, which reveal significant biotin-protein contacts [Athappilly, F. K., and Hendrickson, W. A. (1995) Structure 3, 1407-1419]. Further, the biotin NH1' exchange rates determined for 1.3S show that in the region of optimal activity for TC (pH 5.5-6.5) acid-catalyzed exchange predominates. In this pH range the base-catalyzed rate is too small (< 1 s-1) to account for the turnover rate of the enzyme. Thus, the means by which the N1' atom is activated for nucleophilic attack of the carboxyl group in methylmalonyl-CoA does not appear to depend on interactions within the 1.3S subunit alone; rather activation must occur at the interfaces of the subunits in the holoenzyme.

Probing the chemistries of the substrate and flavin ring system of p-hydroxybenzoate hydroxylase by raman difference spectroscopy

Details of the substrate, p-hydroxybenzoate, and substrate analog, p-aminobenzoate, binding to p-hydroxybenzoate hydroxylase have been elicited by Raman difference spectroscopy. Deep red (752 nm) excitation was used to avoid interference from a fluorescence background. The Raman data provide information on changes in the ligand upon binding as well as changes in the flavin ring system of the enzyme in the enzyme-substrate complex. For p-aminobenzoate, its three most intense Raman features, due to a phenyl mode (1607 cm-1) and carboxylate stretching (1383 cm-1) and scissoring (863 cm-1) motions, are little perturbed upon binding and show no changes in the pH range 6.5-8.5. However, changes in a number of spectral features associated with isoalloxazine modes in this pH range are evidence for a protonation/deprotonation event occurring in or near the active site. A feature in the difference spectrum of the complex at 1700 cm-1 is assigned to the stretch of the 4C&dbd;O group of the isoalloxazine; the relatively narrow profile of this feature is due to the ring being held in a rigid network of hydrogen bonds as demonstrated by the X-ray-derived structure [Schreuder, H. A., Prick, P. A. J., Wierenga, R. K., Vriend, G., Wilson, K. S., Hol, W. G. J., & Drenth, J. (1989) J. Mol. Biol. 208, 679-696]. The absence of a corresponding negative band in the spectrum near 1725 cm-1 shows that in the enzyme, in the absence of ligand, the 4C&dbd;O peak is "washed out" by a fluctuating series of hydrogen bonds to water molecules which penetrate to the flavin ring, resulting in a broad C&dbd;O stretching feature which escapes detection in the difference spectrum. For p-hydroxybenzoate, upon complexation, the -COO- symmetric stretch shifts 10 cm-1, which is ascribed to the formation of the salt bridge to the guanidinium of Arg 214, seen in the X-ray structure. This is in contrast with the results for the complex involving the p-amino analog where no shift in the carboxylate mode is detected and demonstrates an advantage of using vibrational spectroscopy as a fine probe of active site interactions, since the X-ray structures for the p-amino and p-hydroxy analog complexes indicate that the structures in the -COO- group guanidinium regions are the same. The Raman difference data for the substrate complex in the 1700 cm-1 region closely resemble those for the p-amino analog, indicating that in both cases the 4C&dbd;O group is participating in a rigid hydrogen bonding network in the complexes with ligand but is in a more dynamic hydrogen bonding environment involving water molecules in the unliganded enzyme. In order to measure the pKa of the -OH group in bound p-hydroxybenzoate, the substrate was labeled with 18O in both -COO- oxygen atoms. By subtracting the Raman spectrum of the complex with labeled substrate from that with unlabeled substrate, a simple difference spectrum was obtained with features involving the -COO- group alone. These features were used to measure the pKa of the ring hydroxyl group which was found to be 8.3. The value determined from absorption spectroscopy is 7.4, and possible reasons for the discrepancy are discussed. Both methods are in accord, however, in that they show that the pKa of the bound substrate is substantially below that for the free, a device which assists in the hydroxylation at the 3-position.

Raman study of the polarizing forces promoting catalysis in 4-chlorobenzoate-CoA dehalogenase

The enzyme 4-chlorobenzoate-CoA dehalogenase catalyzes the hydrolysis of 4-chlorobenzoate-CoA (4-CBA-CoA) to 4-hydroxybenzoyl-CoA (4-HBA-CoA). In order to facilitate electrophilic catalysis, the dehalogenase utilizes a strong polarizing interaction between the active site residues and the benzoyl portion of the substrate [Taylor, K. L., et al. (1995) Biochemistry 34, 13881]. As a result of this interaction, the normal modes of the benzoyl moiety of the bound 4-HBA-CoA undergo a drastic rearrangement as shown by Raman spectroscopy. Here, we present Raman difference spectroscopic data on the product-enzyme complex where the product's benzoyl carbonyl is labeled with 18O (C=18O) or 13C (13C=O) or where the 4-OH group is labeled with 18O. The data demonstrate that the carbonyl group participates in the most intense normal modes occurring in the Raman spectrum in the 1520-1560 cm-1 region. The substrate analog 4-methylbenzoate-CoA (4-MeBA-CoA) has also been characterized by Raman difference spectroscopy in its free form and bound to the dehalogenase. Upon binding, the 4-MeBA-CoA shows evidence of polarization within the delocalized pi-electrons, but to a lesser extent compared to that seen for the product. The use of 4-MeBA-CoA labeled with 18O at the carbonyl enables us to estimate the degree of electron polarization within the C=O group of the bound 4-MeBA-CoA. The C=O stretching frequency occurs near 1663 cm-1 in non-hydrogen bonding solvents such as CCl4, near 1650 cm-1 in aqueous solution, and near 1610 cm-1 in the active site of dehalogenase. From model studies, we can estimate that in the active site the carbonyl group behaves as though it is being polarized by hydrogen bonds approximately 57 kJ mol-1 in strength. Major contributions to this polarization come from hydrogen bonds from the peptide NHs of Gly114 and Phe64. However, an additional contribution, which may account for up to half of the observed shift in nuC=O, originates in the electrostatic field due to the alpha-helix dipole from residues 121-114. The helix which terminates at Gly114, near the C=O group of the bound benzoyl, provides a dipolar electrostatic component which contributes to the polarization of the C=O bond and to the polarization of the entire benzoyl moiety. The effect of both the helix dipole and the hydrogen bonds on the C=O is a "pull" of electrons onto the carbonyl oxygen, which, in turn, polarizes the electron distribution within the benzoyl pi-electron system. The ability of these two factors to polarize the electrons within the benzoyl moiety is increased by the environment about the benzoyl ring; it is surrounded by hydrophobic residues which provide a low-dielectric constant microenvironment. Electron polarization promotes catalysis by reducing electron density at the C4 position of the benzoyl ring, thereby assisting attack by the side chain of Asp145. An FTIR study on the model compound 4-methylbenzoyl S-ethyl thioester, binding to a number of hydrogen bonding donors in CCl4, is described and is used to relate the observed shift of the C=O stretching mode of 4-MeBA-CoA in the active site to the hydrogen bonding strength value. Since the shift of the C=O frequency upon binding is due to hydrogen bonding and helix dipole effects, we refer to this bonding strength as the effective hydrogen bonding strength.

Active site properties of the 3C proteinase from hepatitis A virus (a hybrid cysteine/serine protease) probed by Raman spectroscopy

Although the HAV 3C proteinase is a cysteine protease, it displays an active site configuration which resembles mammalian serine proteases and is structurally distinct from the papain superfamily of thiol proteases. Given the interesting serine/cysteine protease hybrid nature of HAV 3C, we have probed its active site properties via the Raman spectra of the acyl enzyme, 5-methylthiophene acryloyl HAV 3C, using the C24S variant of the enzyme to obtain stoichiometric acylation. The Raman difference spectral data show that the major population of the acyl groups in the active site experiences electron polarization intermediate between that in the papain superfamily and that in a nonpolarizing site. This is evidenced by the values of the acyl group ethylenic stretching frequency which occur near 1602 cm(-1) in a nonpolarizing environment, at 1588 cm(-1) when bound to HAV 3C (C24S), and at 1579 cm(-1) in acyl papains. The value of the electronic absorption maximum for the HAV 3C (C24S) acyl enzyme and the deacylation rate constant fit the correlation developed for the papain superfamily, suggesting that for HAV 3C too, polarizing forces in the active site can contribute to rate acceleration via transition state stabilization. The major population in the active site is s-cis about the acyl group's C1-C2 bond, but there is a second population that is s-trans, and this secondary population is not polarized. The two populations are evidenced by the presence of two sets of marker bands for s-cis and s-trans in the Raman spectra, which occur principally in the C=C stretching region near 1600 cm(-1), in the C-C stretching region near 1100 cm(-1), and near 560 cm(-1). The positions of the acyl carbonyl features in the Raman spectra point to hydrogen-bonding strengths of 20-25 kJ mol(-1) between the C=O and H-bonding donors in the active site. The 5-methylthiophene acryloyl HAV 3C (C24S) is a relatively unreactive acyl enzyme, deacylating with a pKa of 7.1 and a rate constant of 0.000 31 s(-1) at pH 9. Unlike most other cysteine or serine protease acyl enzymes characterized by Raman spectroscopy, no changes in the Raman spectrum could be detected with changes in pH.

Deacylation and reacylation for a series of acyl cysteine proteases, including acyl groups derived from novel chromophoric substrates

In order to investigate structure-reactivity relationships within a series of acyl cysteine proteases [Doran, J. D., & Carey, P. R. (1996) Biochemistry 35, 12495-12502], deacylation kinetics have been measured for a number of acyl intermediates involving members of the papain superfamily. Derivatives of the "simple" chromophoric ligand (5-methylthienyl)acrylate (5MTA) and those based on two chromophorically labeled derivatives of peptidyl substrates, viz., 2-[(N-acetyl-L-phenylalanyl)amino]-3-(5-methylthienyl)acrylate (Phe5MTA) and 2-[(N-acetyl-L-alanyl)amino]-3-(5-methylthienyl)acrylate (Ala5MTA), were used to create acyl enzyme adducts with papain, cathepsin B, and cathepsin L. The chromophoric specific substrates were designed to utilize hydrogen-bonding and hydrophobic interactions which are known to be important in promoting catalysis by papain. For cathepsins B and L, removing one of the hydrogen-bonding donors making up the putative oxyanion hole retards deacylation by 3-25-fold, demonstrating that the oxyanion hole has a modest effect on catalysis for these substrates. With the above substrates and the wild-type and oxyanion hole mutants, the values of the deacylation rate constants stretch over a 214-fold range, from 0.07 to 15 x 10(-3) s-1. The pKa for deacylation of [(5-methylthienyl)-acryloyl]papain is 4.9, close to that reported for similar papain intermediates, while that for Ala5MTA-papain is at 3.5, which in the latter likely represents the effect of the P1-S1 and P2-S2 interactions on the environment of histidine-159. For the Phe5MTA-papain the extent of deacylation was found to depend on the pH and the starting acyl enzyme concentration. A simple model has been derived which accounts quantitatively for this behavior, using the assumptions that the protonated form of the acyl product reacylates the enzyme and that in the pH range 5.0-7.5 the ionization of active-site groups has no effect on reacylation. The validity of the first assumption was demonstrated by following the deacylation of Phe5MTA-papain in the presence of the potent inhibitor E-64 [1-(L-trans-epoxysuccinyl-L-leucylamino)-4-guanidinobutane], whereupon complete deacylation occurred at all pHs with a pKa identical to that for Ala5MTA-papain, viz., 3.5.

Alpha-helix dipoles and catalysis: absorption and Raman spectroscopic studies of acyl cysteine proteases

Raman and absorption spectroscopic data are combined with the deacylation rate constants for a series of acyl cysteine proteases to provide insight into the role of alpha-helix dipoles in rate acceleration. The Raman spectra, obtained by Raman difference spectroscopy, of (5-methylthienyl)acryloyl adducts with papain, cathepsins B and L, and two oxyanion hole mutants of cathepsin B (Q23S and Q23A) show that extensive polarization throughout the pai-electron chain occurs for the bound acyl group in the active sites. A similar result is obtained using the specific chromophoric substrate ethyl 2-[(N-acetyl-L-phenylalanyl)amino]-3-(5-methylthienyl)acrylate. By using 13C = O substitution it is possible to detect the acyl C = O stretching frequency, vC = O, for each acyl enzyme. A correlation between vC = O and log k3, where k3 is the deacylation rate constant, is found where vC = O increases with increasing reactivity. This is exactly the opposite sense to the relationship found for a series of acyl serine proteases [Carey & Tonge (1995) Acc. Chem. Res. 28, 8]. The opposite trend in the direction of the correlation for the acyl cysteine proteases is ascribed to the strong electron polarizing forces in the active site, due principally to the active-site alpha-helix dipole, giving rise to canonical (valence bond) forms of the acyl group which change the hybridization about the C = O carbon atom. A correlation is also observed between the absorption maximum, lambda max, and log k3 for each acyl cysteine protease. As the deacylation rate increases, 214-fold across the series, lambda max red-shifts from 367 to 384 nm. It is proposed that differential interactions between the active site's alpha-helix dipole and the acyl chromophore give rise to the observed changes in lambda max, with the red shift being caused principally by interactions with the excited electronic state, which has a high degree of charge separation, and the dipole. Similar interactions between the dipole and the negatively charged tetrahedral intermediate, which resembles the transition state, are proposed as the source of differential rates in deacylation. It is interesting to note that similar energies are operating in both cases. A shift in lambda max from 367 to 384 nm corresponds to a change in electronic absorption transition energies of 3.2 kcal/mol and a change of deacylation rate constants of 214-fold also corresponds to a change of activation energies of 3.2 kcal/mol.

Electrostatic modification of the active site of myoglobin: characterization of the proximal Ser92Asp variant

The structural and functional consequences of the introduction of a negatively charged amino acid into the active site of horse heart myoglobin have been investigated by replacement of the proximal Ser92 residue (F7) with an aspartyl residue (Ser92Asp). UV-visible absorption maxima of various ferrous and ferric derivatives and low-temperature EPR spectra of the metaquo (metMb) derivative indicate that the active site coordination geometry has not been perturbed significantly in the variant. 1H-NMR spectroscopy provides direct evidence for the existence of a distal water molecule as the sixth ligand in the oxidized form of the variant at pD 5.7. Spectrophotometric pH titration of the Ser92Asp variant is consistent with this finding and with a pKa = 8.90 +/- 0.02 [25.0 degrees C, mu = 0.10 M (NaCl)] for titration of the distal water molecule, identical to the value reported for the wild-type protein. X-ray crystallography of the metMb derivative indicates that the heme substituents conserve their orientations in the variant protein, except for a slight reorientation of the pyrrole A propionate group to which Ser92 normally hydrogen bonds and reorientation of the carboxyl end of the pyrrole D propionate group. No change is observed in conformation of the proximal (His93) or distal (Wat156) heme ligands. 1H-NMR spectroscopy of the metMbCN form of the protein indicates that a slight rotation of the proximal His93 ligand has occurred in this derivative. Resonance Raman experiments indicate increased conformational heterogeneity in the proximal pocket of the variant. Failure to detect electron density for the Asp residue in the X-ray diffraction map of the variant protein and high average thermal factors for the pyrrole A propionate substituent are consistent with this observation. The variant exhibits novel pH-dependent behavior in the metMb form, as shown by 1H-NMR spectroscopy, and provides evidence for a heme-linked titratable group with a pKa of 5.4 in this derivative. The metMbCN and deoxyMb derivatives also exhibit pH-dependent behavior, with pKas of 5.60 +/- 0.07 and 6.60 +/- 0.07, respectively, compared to the wild-type values of 5.4 +/- 0.04 and 5.8 +/- 0.1. The heme-linked ionizable group is proposed to be His97 in all three derivatives. The reduction potential of the variant is 72 +/- 2 mV vs SHE [25.0 degrees C, mu = 0.10 M (phosphate), pH 6.0], an increase of 8 mV over the wild-type value. The possible influence of a number of variables on the magnitude of the reduction potential in myoglobin and other heme proteins is discussed.

Evidence for electrophilic catalysis in the 4-chlorobenzoyl-CoA dehalogenase reaction: UV, Raman, and 13C-NMR spectral studies of dehalogenase complexes of benzoyl-CoA adducts

This paper reports on the mechanism of substrate activation by the enzyme 4-chlorobenzoyl coenzyme A dehalogenase. This enzyme catalyzes the hydrolytic dehalogenation of 4-chlorobenzoyl coenzyme A (4-CBA-CoA) to form 4-hydroxybenzoyl coenzyme A (4-HBA-CoA). The mechanism of this reaction is known to involve attack of an active site carboxylate (Asp or Glu side chain) at C(4) of the substrate benzoyl ring to form a Meisenheimer complex. Loss of chloride ion from this intermediate results in the formation of an arylated enzyme intermediate. The arylated enzyme is hydrolyzed to free enzyme plus 4-HBA-CoA by the addition of water at the acyl carbon [Yang, G., Liang, P.-H., & Dunaway-Mariano, D. (1994) Biochemistry 33, 8527]. The present studies have focused on the activation of the 4-CBA-CoA for nucleophilic attack by the active site carboxylate group. UV-visible, 13C-NMR, and Raman spectroscopic techniques were used to monitor changes in the distribution of the pi electrons of the benzoyl moiety of benzoyl-CoA adducts [substituted at C(4) with methyl (4-MeBA-CoA), methoxy (4-MeOBA-CoA), or hydroxyl (4-HBA-CoA) groups or at C(2) or C(3) with a hydroxyl group (2-HBA-CoA and 3-HBA-CoA)] resulting from the binding of these ligands to the dehalogenase active site. The UV-visible spectra measured for 4-HBA-CoA in aqueous buffer at pH 7.5 and in the dehalogenase active site revealed that a large red shift (from 292 to 373 nm) in the lambda max of the benzoyl moiety occurs upon binding.(ABSTRACT TRUNCATED AT 250 WORDS)

Abnormally high pKa of an active-site glutamic acid residue in Bacillus circulans xylanase. The role of electrostatic interactions

The active site of Bacillus circulans xylanase (1,4-beta-D-xylanohydrolase, EC 3.2.1.8) contains two glutamic acid residues, Glu78 and Glu172, which are crucial for the catalytic activity of the enzyme. Fourier-transform infrared spectroscopy was used to determine the ionization state of these residues as a function of pH. For the wild-type enzyme, titration of one of the carboxylate groups occurs at pH 6.8. This titration is absent in the Glu78-->Gln and Glu172-->Gln variants of the enzyme. This, together with crystallographic data, indicates that Glu172 has an abnormally high pKa of 6.8, caused largely by electrostatic interactions of this residue with the proximal Glu78. Differential scanning calorimetry experiments with the wild-type xylanase and a number of its mutants have shown that the presence of two nearby carboxyl groups results in a pH-dependent destabilization of the protein structure.

Electronic rearrangement induced by substrate analog binding to the enoyl-CoA hydratase active site: evidence for substrate activation

A series of alpha,beta unsaturated CoA thiol esters have been characterized spectroscopically when they form noncovalent complexes at the active site of enoyl-CoA hydratase. The UV spectra of all of the thiol esters display significant red shifts when the esters are bound to the crotonase active site. The red shift increases with the ability of a para substituent of substituted cinnamoyl-CoA thiol esters to donate electrons by resonance. The affinity of the substituted cinnamoyl-CoA thiol esters is enhanced by electron-donating substituents, with the slope of the log of the ratio of the inhibition constants versus sigma p+ being near unity. Affinity is also increased by either para or meta electron-withdrawing substituents, suggesting that the enzyme stabilizes a partial positive charge at C-3. Binding to crotonase was shown to decrease the shielding of [3-13C,3-2H]cinnamoyl-CoA by +3.2 ppm, consistent with an increased partial positive charge at C-3. The Raman spectra of cinnamoyl-CoA bound at the crotonase active site similarly reflect the significant electronic ground state changes in the pi electronic structure of the bound substrate. These data show that a major rearrangement of electrons occurs in the acryloyl portion of the cinnamoyl group upon binding, while only a minor perturbation occurs to the distribution of electrons in the phenyl ring.(ABSTRACT TRUNCATED AT 250 WORDS)

Forces, bond lengths, and reactivity: fundamental insight into the mechanism of enzyme catalysis

Comparison of spectroscopic, kinetic, and thermodynamic data for a series of functioning acylserine proteases suggests that the observed variation in deacylation rates can be accounted for by changes in the properties of the acyl-enzyme's ground state. The acyl-enzyme's catalytically crucial acyl carbonyl group is probed by resonance Raman spectroscopy. Its spectral frequency is used to gauge both the carbonyl bond length and the strength of hydrogen bonding (originating from groups making up the oxyanion hole) to the carbonyl oxygen atom. As the deacylation rate increases 16,300-fold through the series, a shift in carbonyl frequency, vC = O, of -54 cm-1 corresponds to a carbonyl bond length increase of 0.025 A. The decrease in vC = O is also consistent with an increase in hydrogen bond donor enthalpy of -27 kJ mol-1. Interestingly, this value resembles closely the decrease in activation energy for deacylation through the series, 24 kJ mol-1, demonstrating that the hydrogen bonds to the carbonyl oxygen atom can provide sufficient energy to account for the observed rate accelerations.

Resonance Raman spectroscopic and kinetic consequences of a nitrogen ... sulphur enzyme-substrate contact in a series of dithioacylpapains

The resonance Raman (RR) spectroscopic, conformational, and kinetic properties of six dithioacylpapain intermediates have been examined. Five of the intermediates are of the form N-(methyloxycarbonyl)-X-glycine-C(= S)S-papain, where X is L-phenyl-alanine, D-phenylalanine, glycine, L-phenylglycine, or D-phenylglycine. The sixth intermediate is N-phenylacetyl-glycine-C(= S)S-papain. Throughout the series there is an approximately 50-fold variation in kcat, the rate constant for deacylation, and a 1750-fold variation in kcat/KM. Existing RR spectra structure correlations allow us to define the torsional angles in the NH-CH2-C(= S)-S-CH2-CH fragment of the functioning intermediates. The values of these angles for each bound substrate appear to be very similar, with the substrates assuming a B-type conformer such that the nitrogen atom of the P1 glycine residue is cis to the thiol sulphur atom of cysteine-25. For each intermediate, the C(= S)S-CH2CH torsional angle is approximately -90 degrees, whereas for the SCH2-CH torisonal angle the cysteine-25 thiol sulphur (S) and cysteine-25 C alpha hydrogen (H) atoms are approximately trans. The three acyl-enzymes with the lowest catalytic rate constants, viz. N-(methyloxycarbonyl)-glycine-glycine-, N-(methyloxycarbonyl)-L-phenylglycine-glycine-, or N-(phenylacetyl)-glycine-dithioacylpapains, have atypical RR spectra in that they show a feature of medium intensity in the 1,085-cm-1 region. This band is sensitive to NH to ND exchange of the P1 glycine residues' (-NH-) function and, thus, the corresponding mode involves an excursion of the NH hydrogen. It is hypothesized that the high intensity is due to a particularly strong interaction between the P1 glycine nitrogen atom and the thiol sulphur of cysteine-25, which also has the effect of retarding deacylation, because the nitrogen . . . sulphur contact has to be broken in the rate-determining step.

Resonance Raman and Fourier transform infrared spectroscopic studies of the acyl carbonyl group in [3-(5-methyl-2-thienyl)acryloyl]chymotrypsin: evidence for artifacts in the spectra obtained by both techniques

The acyl carbonyl group of [3-(5-methyl-2-thienyl)acryloyl]chymotrypsin (5MeTA-chymotrypsin) has been investigated by using both resonance Raman (RR) and Fourier transform infrared (FTIR) spectroscopies. The spectrum of the acyl-enzyme carbonyl group has been obtained as a function of pH over the range 3.0-10.0 in the RR experiments and over the range 3.4-7.6 (p2H) in the FTIR experiments. The carbonyl spectral profiles obtained by using FTIR spectroscopy are substantially different from the carbonyl profiles obtained by using RR spectroscopy. The FTIR spectra were obtained by subtracting the spectrum of the free enzyme from that of the acyl-enzyme. Use of the active-site inhibitor phenylmethanesulfonyl fluoride demonstrates that part of the intensity observed in the FTIR spectra of 5MeTA-chymotrypsin is due to a subtraction artifact giving rise to enzyme-associated bands, probably from peptide groups perturbed by substrate binding. The enzyme bands can be removed by subtracting the FTIR spectrum of 13C=O acyl-enzyme from that of 12C=O acyl-enzyme. Additionally, this procedure reveals that one of the acyl-enzyme carbonyl bands observed at 1727 cm-1 using RR spectroscopy is absent in the FTIR acyl-enzyme spectrum. However, a feature near 1720 cm-1 can be induced in the FTIR spectrum by actinic light in the near-UV region. Thus, it is proposed that the 1727 cm-1 RR carbonyl band results from a population of acyl-enzymes which is generated by exposure to the laser beam during RR data collection. When both the RR and FTIR data are adjusted to remove artifacts, they provide essentially identical carbonyl stretching profiles.

The mechanism of sunlight-mediated inactivation of Bacillus thuringiensis crystals

Detailed photostability studies were carried out using purified delta-endotoxin crystals from Bacillus thuringiensis subspecies HD-1 and HD-73. The mechanism and time course of sunlight inactivation was investigated by: (a) monitoring the tryptophan damage in the intact crystals by Raman spectroscopy, (b) amino acid analysis and (c) biological assays using insects. The results demonstrate that, for purified HD-1 or HD-73 crystals, the 300-380 nm range of the solar spectrum is largely responsible for bringing about crystal damage and consequent loss of toxicity. Purified Bacillus thuringiensis crystals that were exposed to fermentation liquor after cell lysis were more quickly degraded by sunlight than were crystals from cells that were lysed in water. This effect is attributed to adsorption of chromophores by crystals exposed to the fermenter liquor and the subsequent ability of these chromophores to act as photosensitizers. The importance of a photosensitization mechanism in crystal degradation was further emphasized by irradiating Bacillus thuringiensis crystals in vacuo. The latter crystals were found to be less damaged (20% tryptophan loss after 24 h irradiation by the solar spectrum) compared with crystals from the same sample irradiated in air (60% (60% tryptophan loss). Other methods of decreasing exposure of the crystals to oxygen, e.g. by using glycerol as a humectant, were also found to be successful in controlling photodamage. The results concerning photodegradation support a photosensitization mechanism involving the presence of exogenous (and possibly endogenous) chromophores which create singlet oxygen species upon irradiation by light.

Length of the acyl carbonyl bond in acyl-serine proteases correlates with reactivity

Resonance Raman (RR) spectroscopy has been used to obtain the vibrational spectrum of the acyl carbonyl group in a series of acylchymotrypsins and acylsubtilisins at the pH of optimum hydrolysis. The acyl-enzymes, which utilize arylacryloyl acyl groups, include three oxyanion hole mutants of subtilisin BPN', Asn155Leu, Asn155Gln, and Asn155Arg, and encompass a 500-fold range of deacylation rate constants. For each acyl-enzyme a RR carbonyl band has been identified which arises from a population of carbonyl groups undergoing nucleophilic attack in the active site. As the deacylation rate (k3) increases through the series of acyl-enzymes, the carbonyl stretching band (vC = O) is observed to shift to lower frequency, indicating an increase in single bond character of the reactive acyl carbonyl group. Experiments involving the oxyanion hole mutants of subtilisin BPN' indicate that a shift of vC = O to lower frequency results from stronger hydrogen bonding of the acyl carbonyl group in the oxyanion hole. A plot of log k3 against vC = O is linear over the range investigated, demonstrating that the changes in vC = O correlate with the free energy of activation for the deacylation reaction. By use of an empirical correlation between carbonyl frequency (vC = O) and carbonyl bond length (rC = O) it is estimated that rC = O increases by 0.015 A as the deacylation rate increases 500-fold through the series of acyl-enzymes. This change in rC = O is about 7% of that expected for going from a formal C = O double bond in the acyl-enzyme to a formal C-O single bond in the tetrahedral intermediate for deacylation. The data also allow us to estimate the energy needed to extend the acyl carbonyl group along its axis to be 950 kJ mol-1 A-1.

Unusual proteolysis of the protoxin and toxin from Bacillus thuringiensis. Structural implications

Trypsin is shown to generate an insecticidal toxin from the 130-kDa protoxin of Bacillus thuringiensis subsp. kurstaki HD-73 by an unusual proteolytic process. Seven specific cleavages are shown to occur in an ordered sequence starting at the C-terminus of the protoxin and proceeding toward the N-terminal region. At each step, C-terminal fragments of approximately 10 kDa are produced and rapidly proteolyzed to small peptides. The sequential proteolysis ends with a 67-kDa toxin which is resistant to further proteolysis. However, the toxin could be specifically split into two fragments by proteinases as it unfolded under denaturing conditions. Papain cleaved the toxin at glycine 327 to give a 34.5-kDa N-terminal fragment and a 32.3-kDa C-terminal fragment. Similar fragments could be generated by elastase and trypsin. The N-terminal fragment corresponds to the conserved N-terminal domain predicted from the gene-deduced sequence analysis of toxins from various subspecies of B. thuringiensis, and the C-terminal fragment is the predicted hypervariable sequence domain. A double-peaked transition was observed for the toxin by differential scanning calorimetry, consistent with two or more independent folding domains. It is concluded that the N- and C-terminal regions of the protoxin are two multidomain regions which give unique structural and biological properties to the molecule.

Characterization of the cysteine residues and disulphide linkages in the protein crystal of Bacillus thuringiensis

Bacillus thuringiensis produces a 130-140 kDa insecticidal protein in the form of a bipyramidal crystal. The protein in the crystals from the subspecies kurstaki HD-1 and entomocidus was found to contain 16-18 cysteine residues per molecule, present primarily in the disulphide form as cystine. Evidence that all the cysteine residues form symmetrical interchain disulphide linkages in the protein crystal was obtained from the following results: (i) the disulphide diagonal procedure [Brown & Hartley (1966) Biochem. J. 101, 214-228] gave only unpaired cysteic acid peptides in diagonal maps; (ii) the disulphide bridges were shown to be labile in dilute alkali and the crystal protein could be released quantitatively with 1 mM-2-mercaptoethanol; (iii) the thiol groups of the released crystal protein were shown by competitive labelling [Kaplan, Stevenson & Hartley (1971) Biochem. J. 124, 289-299] to have the same chemical properties as exposed groups on the surface of the protein; (iv) the thiol groups in the released crystal protein reacted quantitatively with iodoacetate or iodoacetamide. The finding that all the disulphide linkages in the protein crystal are interchain and symmetrical accounts for its alkali-lability and for the high degree of conservation in the primary structure of the cystine-containing regions of the protein from various subspecies.

Secondary structure of the entomocidal toxin from Bacillus thuringiensis subsp. kurstaki HD-73

The secondary structure of the toxin from Bacillus thuringiensis subsp. kurstaki (Btk) HD-73 was estimated by Raman, infrared, and circular dichroism spectroscopy, and by predictive methods. Circular dichroism and infrared spectroscopy gave an estimate of 33-40% alpha-helix, whereas Raman and predictive methods gave approximately 20%. Raman and circular dichroism spectra, as well as predictive methods, indicated that the toxin contains 32-40% beta-sheet structure, whereas infrared spectroscopy gave a slightly lower estimate. Thus, all of these approaches are in agreement that the native conformation of Btk HD-73 toxin is highly folded and contains considerable amounts of both alpha-helical and beta-sheet structures. No significant differences were detected in the secondary structure of the toxin either in solution or as a hydrated pellet.

Isolation of carboxyl-terminal peptides from proteins by diagonal electrophoresis: application to the entomocidal toxin from Bacillus thuringiensis

A procedure for the selective isolation of the C-terminal peptides from enzymatic digests of proteins is described. The methodology is based on the diagonal electrophoretic procedure described by R. G. Duggleby and H. Kaplan (1975) Anal. Biochem. 65, 346-354). The carboxyl groups in the protein are amidated with [14C]-methylamine followed by enzymatic digestion. Since only the C-terminal peptides lack a free carboxyl group, these peptides will lie on a diagonal line of a two-dimensional electrophoretogram run at pH 2.1 and 4.4. The diagonal line is delineated by autoradiography using [14C]taurine (net charge = 0 at pH 2.1 and 4.4) and [14C]choline (net charge = +1 at pH 2.1 and 4.4). Radioactive C-terminal peptides lie between these markers and can be directly excised for analysis. This procedure permits the detection and selective isolation of C-terminal peptides with minimal losses. The procedure was applied to the test proteins alpha-chymotrypsin and ribonuclease A. It was used to determine the C-terminus of the Bacillus thuringiensis toxin generated by tryptic cleavage of the protoxin.

Direct observation of the titration of substrate carbonyl groups in the active site of alpha-chymotrypsin by resonance Raman spectroscopy

By use of resonance Raman (RR) spectroscopy, the population of the reactive carbonyl group in active acylchymotrypsins has been characterized and correlated with acyl-enzyme reactivity. RR spectra have been obtained, with a flow system and 324- and 337.5-nm excitation, at low and active pH for six acylchymotrypsins, viz., (indoleacryloyl)-, (4-amino-3-nitrocinnamoyl)-, (furylacryloyl)-, [( 5-ethylfuryl)-acryloyl]-, (thienylacryloyl)-, and [( 5-methylthienyl)acryloyl]chymotrypsin. These acyl-enzymes represent a 100-fold range of deacylation rate constants. Good RR spectral quality has enabled us to obtain the vibrational spectrum of the carbonyl group at low and active pH in each acyl-enzyme. The measured pKa of the spectroscopic changes in the carbonyl region is identical with that for the deacylation kinetics, showing that the RR carbonyl features reflect the ionization state of His-57. A carbonyl population has been observed in the active acyl-enzymes in which the carbonyl oxygen atom of the reactive acyl linkage is hydrogen-bonded in the active site. The proportion of this hydrogen-bonded population, with respect to other observed non-hydrogen-bonded species, together with the degree of polarization of the carbonyl bond, as monitored by vC = 0, has been correlated with the deacylation rate constants of the acyl-enzymes. It is proposed that the hydrogen-bonded carbonyl species is located at or near the oxyanion hole and represents the ground state from which deacylation occurs. An increase in the proportion of the hydrogen-bonded population and an increase in polarization of the carbonyl bond result in an increase in deacylation rate constant.(ABSTRACT TRUNCATED AT 250 WORDS)