Engineering of a glycosidase Family 7 cellobiohydrolase to more alkaline pH optimum: the pH behaviour of Trichoderma reesei Cel7A and its E223S/ A224H/L225V/T226A/D262G mutant.

The crystal structures of Family 7 glycohydrolases suggest that a histidine residue near the acid/base catalyst could account for the higher pH optimum of the Humicola insolens endoglucanase Cel7B, than the corresponding Trichoderma reesei enzymes. Modelling studies indicated that introduction of histidine at the homologous position in T. reesei Cel7A (Ala(224)) required additional changes to accommodate the bulkier histidine side chain. X-ray crystallography of the catalytic domain of the E223S/A224H/L225V/T226A/D262G mutant reveals that major differences from the wild-type are confined to the mutations themselves. The introduced histidine residue is in plane with its counterpart in H. insolens Cel7B, but is 1.0 A (=0.1 nm) closer to the acid/base Glu(217) residue, with a 3.1 A contact between N(epsilon2) and O(epsilon1). The pH variation of k(cat)/K(m) for 3,4-dinitrophenyl lactoside hydrolysis was accurately bell-shaped for both wild-type and mutant, with pK(1) shifting from 2.22+/-0.03 in the wild-type to 3.19+/-0.03 in the mutant, and pK(2) shifting from 5.99+/-0.02 to 6.78+/-0.02. With this poor substrate, the ionizations probably represent those of the free enzyme. The relative k(cat) for 2-chloro-4-nitrophenyl lactoside showed similar behaviour. The shift in the mutant pH optimum was associated with lower k(cat)/K(m) values for both lactosides and cellobiosides, and a marginally lower stability. However, k(cat) values for cellobiosides are higher for the mutant. This we attribute to reduced non-productive binding in the +1 and +2 subsites; inhibition by cellobiose is certainly relieved in the mutant. The weaker binding of cellobiose is due to the loss of two water-mediated hydrogen bonds.

Identification of Asp-130 as the catalytic nucleophile in the main alpha-galactosidase from Phanerochaete chrysosporium, a family 27 glycosyl hydrolase.

Characterization of the complete gene sequence encoding the alpha-galactosidase from Phanerochaete chrysosporium confirms that this enzyme is a member of glycosyl hydrolase family 27 [Henrissat, B., and Bairoch, A. (1996) Biochem. J. 316, 695-696]. This family, together with the family 36 alpha-galactosidases, forms glycosyl hydrolase clan GH-D, a superfamily of alpha-galactosidases, alpha-N-acetylgalactosaminidases, and isomaltodextranases which are likely to share a common catalytic mechanism and structural topology. Identification of the active site catalytic nucleophile was achieved by labeling with the mechanism-based inactivator 2',4', 6'-trinitrophenyl 2-deoxy-2,2-difluoro-alpha-D-lyxo-hexopyranoside; this inactivator was synthesized by anomeric deprotection of the known 1,3,4,6-tetra-O-acetyl-2-deoxy-2, 2-difluoro-D-lyxo-hexopyranoside [McCarter, J. D., Adam, M. J., Braun, C., Namchuk, M., Tull, D., and Withers, S. G. (1993) Carbohydr. Res. 249, 77-90], picrylation with picryl fluoride and 2, 6-di-tert-butylpyridine, and O-deacetylation with methanolic HCl. Enzyme inactivation is a result of the formation of a stable 2-deoxy-2,2-difluoro-beta-D-lyxo-hexopyranosyl-enzyme intermediate. Following peptic digestion, comparative liquid chromatographic/mass spectrometric analysis of inactivated and control enzyme samples served to identify the covalently modified peptide. After purification of the labeled peptide, benzylamine was shown to successfully replace the 2-deoxy-2,2-difluoro-D-lyxo-hexopyranosyl peptidyl ester by aminolysis. The labeled amino acid was identified as Asp-130 of the mature protein by further tandem mass spectrometric analysis of the native and derivatized peptides in combination with Edman degradation analysis. Asp-130 is found within the sequence YLKYDNC, which is highly conserved in all known family 27 glycosyl hydrolases.

A new affinity ligand for the isolation of a single 'feruloyl esterase' (FAE-III) from Aspergillus niger.

8-Aminooctyl 5'-S-coniferyl-5'-deoxy-thio-alpha-L-arabinofuranoside has been synthesised and shown to be a selective affinity ligand for the feruloyl esterase III of Aspergillus niger. The hydrolyses of methyl 5-O-coumaroyl, feruloyl, or sinapoyl alpha-L-arabinofuranosides by this enzyme proceed at comparable rates.

Substrate specificity in glycoside hydrolase family 10. Tyrosine 87 and leucine 314 play a pivotal role in discriminating between glucose and xylose binding in the proximal active site of Pseudomonas cellulosa xylanase 10A.

The Pseudomonas family 10 xylanase, Xyl10A, hydrolyzes beta1, 4-linked xylans but exhibits very low activity against aryl-beta-cellobiosides. The family 10 enzyme, Cex, from Cellulomonas fimi, hydrolyzes aryl-beta-cellobiosides more efficiently than does Xyl10A, and the movements of two residues in the -1 and -2 subsites are implicated in this relaxed substrate specificity (Notenboom, V., Birsan, C., Warren, R. A. J., Withers, S. G., and Rose, D. R. (1998) Biochemistry 37, 4751-4758). The three-dimensional structure of Xyl10A suggests that Tyr-87 reduces the affinity of the enzyme for glucose-derived substrates by steric hindrance with the C6-OH in the -2 subsite of the enzyme. Furthermore, Leu-314 impedes the movement of Trp-313 that is necessary to accommodate glucose-derived substrates in the -1 subsite. We have evaluated the catalytic activities of the mutants Y87A, Y87F, L314A, L314A/Y87F, and W313A of Xyl10A. Mutations to Tyr-87 increased and decreased the catalytic efficiency against 4-nitrophenyl-beta-cellobioside and 4-nitrophenyl-beta-xylobioside, respectively. The L314A mutation caused a 200-fold decrease in 4-nitrophenyl-beta-xylobioside activity but did not significantly reduce 4-nitrophenyl-beta-cellobioside hydrolysis. The mutation L314A/Y87A gave a 6500-fold improvement in the hydrolysis of glucose-derived substrates compared with xylose-derived equivalents. These data show that substantial improvements in the ability of Xyl10A to accommodate the C6-OH of glucose-derived substrates are achieved when steric hindrance is removed.

Hydrolyses of alpha- and beta-cellobiosyl fluorides by Cel6A (cellobiohydrolase II) of Trichoderma reesei and Humicola insolens.

We have measured the hydrolyses of alpha- and beta-cellobiosyl fluorides by the Cel6A [cellobiohydrolase II (CBHII)] enzymes of Humicola insolens and Trichoderma reesei, which have essentially identical crystal structures [Varrot, Hastrup, Schülein and Davies (1999) Biochem. J. 337, 297-304]. The beta-fluoride is hydrolysed according to Michaelis-Menten kinetics by both enzymes. When the approximately 2.0% of beta-fluoride which is an inevitable contaminant in all preparations of the alpha-fluoride is hydrolysed by Cel7A (CBHI) of T. reesei before initial-rate measurements are made, both Cel6A enzymes show a sigmoidal dependence of rate on substrate concentration, as well as activation by cellobiose. These kinetics are consistent with the classic Hehre resynthesis-hydrolysis mechanism for glycosidase-catalysed hydrolysis of the 'wrong' glycosyl fluoride for both enzymes. The Michaelis-Menten kinetics of alpha-cellobiosyl fluoride hydrolysis by the T. reesei enzyme, and its inhibition by cellobiose, previously reported [Konstantinidis, Marsden and Sinnott (1993) Biochem. J. 291, 883-888] are withdrawn. (1)H NMR monitoring of the hydrolysis of alpha-cellobiosyl fluoride by both enzymes reveals that in neither case is alpha-cellobiosyl fluoride released into solution in detectable quantities, but instead it appears to be hydrolysed in the enzyme active site as soon as it is formed.

Lignocellulose degradation by Phanerochaete chrysosporium: purification and characterization of the main alpha-galactosidase.

The main alpha-galactosidase was purified to homogeneity, in 30% yield, from a solid culture of Phanerochaete chrysosporium on 1 part wheat bran/2 parts thermomechanical softwood pulp. It is a glycosylated tetramer of 50 kDa peptide chains, which gives the N-terminal sequence ADNGLAITPQMG(?W)NT(?W)NHFG(?W)DIS(?W)DTI. It is remarkably stable, with crude extracts losing no activity over 3 h at 80 degrees C, and the purified enzyme retaining its activity over several months at 4 degrees C. The kinetics of hydrolysis at 25 degrees C of various substrates by this retaining enzyme were measured, absolute parameters being obtained by active-site titration with 2',4',6'-trinitrophenyl 2-deoxy-2, 2-difluoro-alpha-D-galactopyranoside. The variation of kcat/Km for 1-naphthyl-alpha-D-galactopyranoside with pH is bell-shaped, with pK1=1.91 and pK2=5.54. The alphaD(V/K) value for p-nitrophenyl-alpha-D-glucopyranoside is 1.031+/-0.007 at the optimal pH of 3.75 and 1.114+/-0.006 at pH7.00, indicating masking of the intrinsic effect at optimal pH. There is no alpha-2H effect on binding galactose [alphaD(Ki)=0.994+/-0.013]. The enzyme hydrolyses p-nitrophenyl beta-L-arabinopyranoside approximately 510 times slower than the galactoside, but has no detectable activity on the alpha-D-glucopyranoside or alpha-D-mannopyranoside. Hydrolysis of alpha-galactosides with poor leaving groups is Michaelian, but that of substrates with good leaving groups exhibits pronounced apparent substrate inhibition, with Kis values similar to Km values. We attribute this to the binding of the second substrate molecule to a beta-galactopyranosyl-enzyme intermediate, forming an E.betaGal. alphaGalX complex which turns over slowly, if at all. 1-Fluoro-alpha-D-galactopyranosyl fluoride, unlike alpha-D-galactopyranosyl fluoride, is a Michaelian substrate, indicating that the effect of 1-fluorine substitution is greater on the first than on the second step of the enzyme reaction.

Definition of the substrate specificity of the 'sensing' xylanase of Streptomyces cyaneus using xylooligosaccharide and cellooligosaccharide glycosides of 3,4-dinitrophenol.

The title compounds, (Xylp beta (1-->4))nXylp beta-3,4-DNP (n = 0-4) have been made by selective anomeric deprotection of peracetylated xylose oligosaccharides with hydrazine, followed by formation of the trichloroacetimidate, uncatalysed reaction with 3,4-dinitrophenol, and Zemplén deacetylation. The values of k(cat)/K(m) for 3,4-dinitrophenol release from these substrates by xylanase III of Streptomyces cyaneus, expressed in Escherichia coli, increase with increasing n up to n = 2 and then slightly decrease. Since it is known from previous work that in its normal host, the enzyme is produced constitutively at low levels and excreted, these results suggest that the biological function of the enzyme may be to produce small molecule inducers, predominantly xylotriose, from the non-reducing end of the xylan. Activity on cellooligosaccharide glycosides (Glcp beta (1-->4))nGlcp beta-3,4-DNP (n = 0-3) was detected, at a rate about two-and-a-half orders of magnitude less than that observed on the corresponding xylooligosaccharides, indicating that the enzyme is a true xylanase.

Larger increases in sensitivity to paracatalytic inactivation than in catalytic competence during experimental evolution of the second beta-galactosidase of Escherichia coli.

Second-order rate constants (M-1.s-1) at 25 degrees C and pH 7.5 for inactivation of first-generation (ebga and ebgb), second-generation (ebgab and ebgabcd) and third-generation (ebgabcde) experimental evolvants of the title enzyme by 2',4'-dinitrophenyl 2-deoxy-2-fluoro-beta-D-galactopyranoside are 0.042, 0.30, 10, 24 and 57 respectively. Only partial inactivation is observed, except for ebgabcde. At a single high inactivator concentration, inactivation of the wild-type ebgo is also seen. The changes in sensitivity to the paracatalytic inactivator (over a range of 10(3.3)) are larger than changes in kcat/Km for lactose (over a range of 10(2.7)) or nitrophenyl galactosides (over a range of only 10(1.3)), or changes in degalactosylation rate (over a range of 10(1.7)). These data raise the possibility that evolution in the reverse sense, towards insensitivity to a paracatalytic inactivator with a proportionally lower effect on transformation of substrate, may become a mechanism for the development of bacterial resistance to antibiotics that act by paracatalytic enzyme inactivation.

Key residues in subsite F play a critical role in the activity of Pseudomonas fluorescens subspecies cellulosa xylanase A against xylooligosaccharides but not against highly polymeric substrates such as xylan.

In a previous study crystals of Pseudomonas fluorescens subspecies cellulosa xylanase A (XYLA) containing xylopentaose revealed that the terminal nonreducing end glycosidic bond of the oligosaccharide was adjacent to the catalytic residues of the enzyme, suggesting that the xylanase may have an exo-mode of action. However, a cluster of conserved residues in the substrate binding cleft indicated the presence of an additional subsite, designated subsite F. Analysis of the biochemical properties of XYLA revealed that the enzyme was a typical endo-beta1,4-xylanase, providing support for the existence of subsite F. The three-dimensional structure of four family 10 xylanases, including XYLA, revealed several highly conserved residues that are on the surface of the active site cleft. To investigate the role of some of these residues, appropriate mutations of XYLA were constructed, and the biochemical properties of the mutated enzymes were evaluated. N182A hydrolyzed xylotetraose to approximately equal molar quantities of xylotriose, xylobiose, and xylose, while native XYLA cleaved the substrate to primarily xylobiose. These data suggest that N182 is located at the C site of the enzyme. N126A and K47A were less active against xylan and aryl-beta-glycosides than native XYLA. The potential roles of Asn-126 and Lys-47 in the function of the catalytic residues are discussed. E43A and N44A, which are located in the F subsite of XYLA, retained full activity against xylan but were significantly less active than the native enzyme against oligosaccharides smaller than xyloseptaose. These data suggest that the primary role of the F subsite of XYLA is to prevent small oligosaccharides from forming nonproductive enzyme-substrate complexes.

Catalytic consequences of experimental evolution: catalysis by a 'third-generation' evolvant of the second beta-galactosidase of Escherichia coli, ebgabcde, and by ebgabcd, a 'second-generation' evolvant containing two supposedly 'kinetically silent' mutations.

The kinetics of hydrolysis of a series of synthetic substrates by two experimentally evolved forms ('evolvants'), ebgabcd and ebgabcde, of the second beta-galactosidase of Escherichia coli have been measured. The ebgabcd enzyme differs from the wild-type (ebgo) enzyme by Asp92-->Asn (a) and Trp977-->Cys (b) changes in the large subunit, as well as two changes hitherto considered to have no kinetic effect, Ser979-->Gly in the large subunit (c) and Glu122-->Gly in the small subunit (d). The enzyme ebgabcde contains in addition a Glu93-->Lys change in the large subunit (e). Comparison of ebgabcd with ebgab [Elliott, K, Sinnott, Smith, Bommuswamy, Guo, Hall and Zhang (1992) Biochem. J. 282, 155-164] indicates that the c and d changes in fact accelerate the hydrolysis of the glycosyl-enzyme intermediate by a factor of 2.5, and also decrease the charge on the aglycone oxygen atom at the first transition state; the charge on the glycone, however, is unaltered [see K, Konstantinidis, Sinnott and Hall (1993) Biochem. J. 291, 15-17]. The e mutation causes a fall in the degalactosylation rate of about a factor of 3, and its occurrence only together with c and d mutations [Hall, Betts and Wootton (1989) Genetics 123, 635-648] suggests that degalactosylation of a hypothetical ebgabe enzyme would be so slow that the enzyme would have no biological advantage over the ancestral ebgab. The transfer products from galactosyl-ebgabcd and galactosyl-ebgabcde to high concentrations to glucose have been measured; the predominant product is allolactose, but significant quantities of lactose are also formed; however, at apparent kinetic saturation of the galactosyl-enzyme, hydrolysis rather than transfer is the preponderant pathway. A knowledge of the rates of enzyme-catalysed exchange of 18O from [1-18O]galactose to water permits the construction of the free-energy profiles for hydrolysis of lactose by begabcd and ebgabcde. As with the other evolvants, changes in the profile away from the rate-determining transition state are essentially random, and there is no correlation between the changes in the free energies of intermediates and of their flanking transition states. We consider the aggregate of our kinetic data on the ebg system to be telling experimental support for the theoretical objections of Pettersson [Pettersson (1992) Eur. J. Biochem. 206, 289-295 and previous papers] to the Albery-Knowles theory of the evolution of enzyme kinetic activity.

Catalysis by the large subunit of the second beta-galactosidase of Escherichia coli in the absence of the small subunit.

Plasmids containing the ebgAo and ebgAa genes of Escherichia coli under the control of the lac repressor and promoter have been constructed and inserted into Salmonella typhimurium CH3. This system expresses the large subunit of the ebgo and ebga beta-galactosidase in high yield (20-60% of total protein). The large subunits have been purified to homogeneity. As isolated they are tetramers of significant catalytic activity; the N-terminal amino acid residue is Met, but it is not formylated. The kcat. values for a series of aryl galactosides were 6-200-fold reduced from the corresponding values for the holoenzymes. kcat/Km Values for glycosides of acidic aglycones, though, were unchanged, whilst kcat./Km values for galactosides of less acidic aglycones showed a modest (up to 10-fold) decrease. The kcat. values for glycosides of acidic aglycones hydrolysed by ebgo and ebga large subunits were essentially invariant with aglycone pK, suggesting that hydrolysis of the galactosyl-enzyme intermediate had become rate-determining for these substrates. Rate-determining hydrolysis of the glycosyl-enzyme intermediate was confirmed by pre-steady-state measurements and nucleophilic competition with methanol. Absence of the small subunit was thus estimated to cause a 200-fold decrease in degalactosylation rate for ebgo and a 20-fold one for ebga. beta 1g(V/K) values of -0.57 +/- 0.08 for ebgo and -0.54 +/- 0.08 for ebga isolated subunits were significantly more negative than for holoenzymes. It is suggested that the small subunit is associated with the optimal positioning of the electrophilic Mg2+ ions in these enzymes. Use of PCR in the construction of the plasmid also inadvertently led to the production of psi ebgo large subunit in which there was a PCR-introduced Leu9-->His change. Values of kcat. for aryl galactosides, calculated on the assumption that the psi ebgo large subunit, like the ebgo and ebga large subunits, was 100% active as isolated, were about an order of magnitude lower than for true ebgo large subunit, whilst Km values were similar. The very significant kinetic effect of this inadvertant site-undirected mutagenesis indicates that quite large kinetic effects of amino-acid replacements in enzymes may have no obvious mechanistic significance.

Phanerochaete chrysosporium and its natural substrate.

We seek to define more fully how Phanerochaete chrysosporium degrades its natural substrate, lignocellulose. This contribution concerns several relevant topics. Mineralisation of [14C]DHP, as a model for lignin degradation, showed that a set of genetically defined meiotically derived products of strain ME446 differed in their degradative ability and also that, under optimum conditions for mineralisation, extracellular lignin peroxidase activity was absent. Xylanolytic and xylosidase/beta(1-->3) glucanase activities are also described. The complexity of the CBHI gene family is described and differential splicing of a CBHI gene transcript is proposed. In contrast to the multiplicity of CHBI genes there is a single CBHII gene. PCR methods were developed to analyse differential gene expression on different substrates. We have also developed a transformation system involving a reporter construct for the analysis of CBHI promoter function.

Hydrolysis of glycosylpyridinium ions by anomeric-configuration-inverting glycosidases.

The hydrolyses of five beta-D-xylopyranosylpyridinium ions by the beta-D-xylosidase of Bacillus pumilus proceed with kcat values 10(8)-10(9)-fold larger than the rates of spontaneous hydrolysis of the same compounds. Log(kcat) values correlate well with aglycon pK(a) [B1g(V) = -0.52, r = 0.99], whereas the correlation of log(kcat/Km) is poor [r = 0.77; beta 1g(V/K) = approximately -0.6]. The (1-->3)-beta-D-glucanase of Sporotrichum dimorphosporum hydrolyses 4-bromo-2-(beta-D-glucopyranosyl)isoquinolinium ion with a rate enhancement of 10(8). The amyloglucosidase II of Aspergillus niger hydrolyses three alpha-D-glucopyranosylpyridinium ions with rate enhancements of 10(5)-10(8). The efficient hydrolysis of glycosylpyridinium ions by these three inverting glycosidases, the catalytic mechanism of which is unlikely to involve a nucleophile from the enzyme, makes it improbable that the hydrolysis of glycosylpyridinium ions by retaining glycosidases, discovered some years ago, is initiated by addition of a catalytic nucleophilic carboxylate group of the enzyme to the pyridinium ring.

Salmonella typhimurium neuraminidase acts with inversion of configuration.

When the time course of the hydrolysis of identical solutions of p-nitrophenyl N-acetyl-alpha-D-neuraminide by Salmonella typhimurium neuraminidase is monitored by u.v. and by its optical rotation, the rotation change is synchronous with, or even marginally in advance of, the absorbance change. In experiments under the same conditions with influenza-virus neuraminidase, known to react with retention of configuration [Chong, Pegg, Taylor and von Itzstein (1992) Eur. J. Biochem. 207, 335-343], the rotation change is much slower than the absorbance change. The inverting, presumably single-displacement, mode of action of the S. typhimurium enzyme follows from these observations, and the position (92.5% beta) of the slowly established mutarotational equilibrium of N-acetylneuraminic acid [Friebolin, Kunzelmann, Supp, Brossmer, Keilich and Ziegler (1981) Tetrahedron Lett. 22, 1383-1386].

A kinetic-isotope-effect study of catalysis by Vibrio cholerae neuraminidase.

Michaelis-Menten parameters for hydrolysis of seven aryl N-acetyl alpha-D-neuraminides by Vibrio cholerae neuraminidase at pH 5.0 correlate well with the leaving-group pKa (delta pK 3.0; beta 1g (V/K) = -0.73, r = -0.93; beta 1g (V) = -0.25; r = -0.95). The beta-deuterium kinetic-isotope effect, beta D2(V), for the p-nitrophenyl glycoside is the same at the optimum pH of 5.0 (1.059 +/- 0.010) as at pH 8.0 (1.053 +/- 0.010), suggesting that isotope effects are fully expressed with this substrate at the optimum pH. For this substrate at pH 5.0, leaving group 18O effects are 18(V) = 1.040 +/- 0.016 and 18(V/K) = 1.046 +/- 0.015, and individual secondary deuterium effects are beta proRD(V) = 1.037 +/- 0.014, beta proSD(V) = 1.018 +/- 0.015, beta proRD(V/K) = 1.030 +/- 0.017, beta proSD(V/K) = 1.030 +/- 0.017. All isotope effects, and the beta 1g(V/K) value are in accord with the first chemical step being both the first irreversible and the rate-determining step in enzyme turnover, with a transition state in which there is little proton donation to the leaving group, the C-O bond is largely cleaved, there is significant nucleophilic participation, and the sugar ring is in a conformation derived from the ground-state 2C5 chair. The apparent conflict between the beta 1g (V) value of -0.25 with all the kinetic-isotope-effect data can be resolved by the postulation of an interaction between the pi system of the aglycone ring and an anionic or nucleophilic group on the enzyme.

Polarimetry and 13C n.m.r. show that the hydrolyses of beta-D-glucopyranosyl fluoride by beta(1-->3)-glucanases from Phanerochaete chrysosporium and Sporotrichum dimorphosporum have opposite stereochemistries.

The time courses of optical rotation and fluoride ion release during hydrolysis of beta-D-glucopyranosyl fluoride by the beta(1-->3)-glucanase of Phanerochaete chrysosporium (J. L. Copa-Patiño and P. Broda, unpublished work) indicated that the initial sugar product was beta-D-glucopyranose. This was confirmed by monitoring the hydrolysis of 1-[13C]beta-D-glucopyranosyl fluoride by this enzyme with 13C n.m.r. (without proton decoupling). The same two techniques were used to confirm that hydrolysis of beta-D-glucopyranosyl fluoride by the exo beta(-->3)-glucanase of 'Basidiomycete QM 806' (identified as Sporotrichum dimorphosporum) yielded alpha-glucopyranose as first sugar product, in accordance with previous results using laminarin as substrate [Parrish and Reese (1963) Carbohydr. Res. 3, 424-429; Nelson (1970) J. Biol. Chem. 245, 869-872].

Hydrolyses of alpha- and beta-cellobiosyl fluorides by cellobiohydrolases of Trichoderma reesei.

Cellobiohydrolase II hydrolyses alpha- and beta-D-cellobiosyl fluorides to alpha-cellobiose at comparable rates, according to Michaelis-Menten kinetics. The stereochemistry, absence of transfer products and strict hyperbolic kinetics of the hydrolysis of alpha-cellobiosyl fluoride suggest that the mechanism for the alpha-fluoride may be the enzymic counterpart of the SNi reaction observed in the trifluoroethanolysis of alpha-glucopyranosyl fluoride [Sinnott and Jencks (1980) J. Am. Chem. Soc. 102, 2026-2032]. The absolute factors by which this enzyme accelerates fluoride ion release are small and greater for the alpha-fluoride than for the beta, suggesting that its biological function may not be just glycoside hydrolysis. Cellobiohydrolase I hydrolyses only beta-cellobiosyl fluoride, which is, however, an approx. 1-3% contaminant in alpha-cellobiosyl fluoride as prepared and purified by conventional methods. Instrumental assays for the various components of the cellulase complex are discussed.

Large changes of transition-state structure during experimental evolution of an enzyme.

The question of whether, during the evolution of an enzyme, the transition state of the catalysed reaction is largely unchanged, or whether transition state and protein change together, was examined using the egb beta-galactosidases of Escherichia coli. Charge development at the first chemical state was assumed [Konstantinidis and Sinnott (1991) Biochem. J. 279, 587-593] to be proportional to delta delta G++, the ratio of second-order rate constants for the hydrolysis of beta-D-galactopyranosyl fluoride and 1-fluoro-D-galactopyranosyl fluoride, expressed as a free-energy difference. delta delta G++ (kJ.mol-1) falls from 10.4 for wild-type enzyme to 6.8 and 7.2 as a consequence of two different single amino-acid changes (which arise from single evolutionary events), to 6.3 as a consequence of the two amino-acid changes together, and then increases slightly to 7.3 as a consequence of a third single evolutionary change involving three further amino-acid changes.

The catalytic consequences of experimental evolution. Studies on the subunit structure of the second (ebg) beta-galactosidase of Escherichia coli, and on catalysis by ebgab, an experimental evolvant containing two amino acid substitutions.

1. The ratio of ebgA-gene product of ebgC-gene product in the functional aggregate of ebg beta-galactosidases was determined to be 1:1 by isolation of the enzyme from bacteria grown on uniformly radiolabelled amino acids and separation of the subunits by gel-permeation chromatography under denaturing conditions. 2. This datum, taken together with a recalculation of the previous ultracentrifuge data [Hall (1976) J. Mol. Biol. 107, 71-84], analytical gel-permeation chromatography and electron microscopy, strongly suggests an alpha 4 beta 4 quaternary structure for the enzyme. 3. The second chemical step in the enzyme turnover sequence, hydrolysis of the galactosyl-enzyme intermediate, is markedly slower for ebgab, having both Asp-97----Asn and Trp-977----Cys changes in the large subunit, than for ebga (having only the first change) and ebgb (having only the second), and is so slow as to be rate-determining even for an S-glycoside, beta-D-galactopyranosyl thiopicrate, as is shown by nucleophilic competition with methanol. 4. The selectivity of galactosyl-ebgab between water and methanol on a molar basis is 57, similar to the value for galactosyl-ebgb. 5. The equilibrium constant for the hydrolysis of lactose at 37 degrees C is 152 +/- 19 M, that for hydrolysis of allolactose is approx. 44 M and that for hydrolysis of lactulose is approx. 40 M. 6. A comparison of the free-energy profiles for the hydrolyses of lactose catalysed by the double mutant with those for the wild-type and the single mutants reveals that free-energy changes from the two mutations are not in general independently additive, but that the changes generally are in the direction predicted by the theory of Burbaum, Raines, Albery & Knowles [(1989) Biochemistry 28, 9283-9305] for an enzyme catalysing a thermodynamically irreversible reaction. 7. Michaelis-Menten parameters for the hydrolysis of six beta-D-galactopyranosylpyridinium ions and ten aryl beta-galactosides by ebgab were measured. 8. The derived beta 1g values are the same as those for ebgb (which has only the Trp-977----Cys change) and significantly different from those for ebgo (the wild-type enzyme) and ebga. 9. The alpha- and beta-deuterium secondary isotope effects on the hydrolysis of the galactosyl-enzyme of 1.08 and 1.00 are difficult to reconcile with the pyranose ring in this intermediate being in the 4C1 conformation.