Production and characterization of anti-human interferon {gamma} receptor antibody fragments that inhibit cytokine binding to the receptor

Three single-chain antibody fragments that recognize the extracellularhuman interferon receptor -chain (IFNR), and inhibit the bindingof human IFN, have been produced in Escherichia coli. Thesefragments are derived from murine anti-receptor monoclonal antibodies,and comprise the variable heavy (V_H) domain linked to the variablelight (V_L) chain through a 15 amino acid linker [(GGGGS)₃].Using surface plasmon resonance technology (BIAcore), the solubleproteins were shown to retain a high affinity for recombinantIFNR, and by radioimmunoassay to possess high inhibitory activitytowards IFN-binding to human Raji cells. The antibody fragmentsmost likely recognize epitopes that overlap the cytokine bindingsite on the receptor surface. Attempts to dissect further theantibodies to isolated V_H- and V_L-chains and to synthetic linearand cyclic peptides derived from the individual complementaritydetermining regions failed to afford fragments with significantIFNR binding affinity. Nevertheless, these native-like variableregion fragments and petidomimetics derived from them are ofinterest in the design of novel IFNR antagonists.     

Family of G protein {alpha} chains: amphipathic analysis and predicted structure of functional domains

The G proteins transduce hormonal and other signals into regulationof enzymes such as adenylyl cyclase and retinal cGMP phosphodiesterase.Each G protein contains an subunit that binds and hydrolyzesguanine nucleotides and interacts with ß subunitsand specific receptor and effector proteins. Amphipathic andsecondary structure analysis of the primary sequences of fivedifferent chains (bovine _s, _t1 and _t2, mouse _i, and rat _o)predicted the secondary structure of a composite chain (_avg).The chains contain four short regions of sequence homologousto regions in the GDP binding domain of bacterial elongationfactor Tu (EF-Tu). Similarities between the predicted secondarystructures of these regions in _avg and the known secondary structureof EF-Tu allowed us to construct a three-dimensional model ofthe GDP binding domain of _avg. Identification of the GDP bindingdomain of _avg defined three additional domains in the compositepolypeptide. The first includes the amino terminal 41 residuesof _avg, with a predicted am phipathic helical structure; thisdomain may control binding of the chains to the ßcomplex. The second domain, containing predicted ßstrands and helices, several of which are strongly amphipathic,probably contains sequences responsible for interaction of chains with effector enzymes. The predicted structure of thethird domain, containing the carhoxy terminal 100 amino acids,is predominantly ß sheet with an amphipathic helixat the carboxy terminus. We propose that this domain is reponsiblefor receptor binding. Our model should help direct further experimentsinto the structure and function of the G protein chain.     

The structure-function relationship of the lipases from Pseudomonas aeruginosa and Bacillus subtilis

Within the BRIDGE T-project on lipases we investigate the structure-functionrelationships of the lipases from Bacillus subtilis and Pseudomonasaeruginosa. Construction of an overproducing Bacillus. strainallowed the purification of > 100 mg lipase from 30 l culturesupernatant. After testing a large variety of crystallizationconditions, the Bacillus lipase gave crystals of reasonablequality in PEG-4000 (38-45%), Na₂SO₄ and octyl-ß-glucosideat 22°C, pH 9.0. A 2.5 Å; dataset has been obtainedwhich is complete from 15 to 2.5 A resolution. P.aeruginosawild-type strain PAC1R was fermented using conditions of maximumlipase production. More than 90% of the lipase was cell boundand could be solubilized by treatment of the cells with TritonX-100. This permitted the purification of 50 mg lipase. So far,no crystals of sufficient quality were obtained. Comparisonof the model we built for the Pseudomonas lipase, on the basisof sequences and structures of various hydrolases which werefound to possess a common folding pattern (/ß hydrolasefold), with the X-ray structure of the P.glumae lipase revealedthat it is possible to correctly build the structure of thecore of a protein even in the absence of obvious sequence homologywith a protein of known 3-D structure.     

Improvement of turn structure prediction by molecular dynamics: a case study of {alpha}1-purothionin

Because of the problems in predicting a correct conformationfor loop regions in homology-based prediction, disagreementsare often found between the predicted models and the refinedX-ray structures of the same protein in loop regions. Such asituation has been encountered for ₁-purothionin (₁-PT). Hence,attempts have been made to improve the predicted model of ₁PTby limited molecular dynamics using both AMBER and XPLOR. Withmolecular dynamics, the previously predicted incorrect turnregion reverts to the correct conformation as seen in the X-rayrefined structure. In contrast to the model which is not subjectedto molecular dynamics, the improved model refines with the X-raydata of ₁PT in fewer cycles, without any manual rebuilding andwith comparable or better refinement statistics. Also, the improvedmodel serves as a better starting model in the determinationof the structure with the molecular replacement methods.     

Modeling the uncleaved serpin antichymotrypsin and its chymotrypsin complex

In order to provide a structural reference for protein engineeringexperiments involving the serpin ₁-antichymotrypsin (ACT) andits complexes with chymotrypsin and DNA, a homology model ofACT has been constructed based on the 3-D structure of the relatedprotein ovalbumin [29% identical and 44% similar; see Stein,P., Leslie, A., Finch, J., Turnell, W., McLaughlin, P. and Carrell,R. (1990) Nature, 347, 99–102]. After mapping the aminoacid sequence of ACT onto the peptide backbone of ovalbumin,the resulting model was subjected to simulated annealing andenergy minimization. Overall, the final ACT model is structurallysimilar to ovalbumin, although the 2.4 Å root mean squaredeviation of corresponding C atoms reflects the presence ofregions exhibiting notable structural differences. The hydrogenbond stereochemistry of the ACT model is consistent with patternsfound in high resolution protein structures and 92% of its backboneatoms have acceptable conformations when evaluated in a Ramachandrananalysis. Significantly, the homology model serves as a structuralreference for protein engineering experiments aimed at redesigningthe functional properties of ACT, particularly with regard toits protease-bound conformation. Additionally, the homologymodel may be useful as a probe for solving the crystal structuresof certain ACT variants (e.g. Thr345 Arg) by molecular replacementmethods. Ultimately, the homology approach may be applied towardthe construction of other serpin models starting with an experimentallydetermined structure of uncleaved ACT as a template.     

Strong inhibition of fibrinogen binding to platelet receptor {alpha}IIb{beta}3 by RGD sequences installed into a presentation scaffold

In order to probe the structural constraints on binding of RGDsequences to the platelet receptor _IIbß₃ we have usedrecombinant DNA techniques to install the RGD sequence into‘presentation scaffolds’, small proteins of known3-D structure chosen to present guest sequences in constrainedorientations. Using Escherichia coli expression systems we madesequence variants in which loop residues of the immunoglobulinV_L domain REI and of human interleukin-1ß were replaced(without changing polypeptide length) by the RGD sequence atpositions predicted, based on small molecule studies, to orientthe RGD moiety into an active conformation. These variants donot compete for fibrinogen binding to _IIbß₃ up toalmost 1 mM concentration. Unfolded or proteolytically fragmentedforms of these same proteins do compete, however, showing thatthe RGD sequences in the mutants must be prohibited from bindingby constraints imposed by scaffold structure. To suppress theeffects of such structural constraints we constructed two sequencevariants in which RGD-containing sequences 42–57 or 44–55from the snake venom platelet antagonist kistrin were inserted(this increasing the length of the loop) into the third complementaritydetermining loop of REI. Both of these variants compete stronglyfor fibrinogen binding with IC₅₀s in the nM range. These results,plus data on kistrin-related peptides also presented here, suggestthat the molecular scaffold REI is capable of providing to aninstalled sequence a structural context and conformation beneficialto binding. The results also suggest that in order to bind wellto _IIbß₃, RGD sequences in protein ligands must eitherproject significantly from the surface of the scaffold and/orretain a degree of conformational flexibility within the scaffold.Molecular scaffolds like REI should prove useful in the elucidationof structure-function relationships and the discovery of newactive sequences, and may also serve as the basis for noveltherapeutic agents.     

Modelling the polypeptide backbone with 'spare parts' from known protein structures

An automatic procedure for building a protein polyalanine backbonefrom C positions and ‘spare parts’ retrieved froma data base of 66 high-resolution protein structures is described.Protein backbones are constructed from over-lapping fragmentsof variable length, which allows the backbone of regular secondarystructure elements to be built in one block. The procedure isshown to yield backbones which compare very favourably withthose from highly refined X-ray structures (r.m.s. deviationbetween generated and crystal structures <lÅ). Themethod is furthermore quite insensitive to experimental errorsin C positions as well as to the size of the data base, andis seen to yield valuable insight into the relationships betweensequence and 3-D structure: one example on triose phosphateisomerase, a ß-barrel protein, shows that ßloops can be considered as structurally more uncommon than ßloops. The ‘spare parts’ approach is also foundto be useful for general-purpose modelling of local structuralchanges produced by insertion or deletion of residues. It should,however, be used with caution. Crude selection criteria basedsolely on fragment length and geometric fit to the loop baseregions yield realistic backbones in about two-thirds of thetest cases (r.m.s. deviations from refined crystal structure{small tilde}lÅ). In the remaining cases, sequence information,in particular the presence of glycine residues which tend toadopt more unusual backbone conformations, must be consideredto obtain comparable results.     

An evaluation of the performance of an automated procedure for comparative modelling of protein tertiary structure

A 3-D model of a protein can be constructed from its amino acidsequence and the 3-D structures of one or more homologues byannealing three sets of fragments: the structurally conservedregions, structurally variable regions and the side chains.The method encoded in the computer program COMPOSER was assessedby generating 3-D models of eight proteins whose crystal structuresare already known and for which 3-D structures of homologuesare available. In the structurally conserved regions, differencesbetween modelled and X-ray structures are smaller than the differencesbetween the X-ray structures of the modelled protein and thehomologues used to build the model. When several homologuesare used, the contributions of the known structures are weighted,preferably by the square of sequence similarity; this is especiallyimportant when the similarities of the homologues to the modelledstructure differ greatly. The ‘collar’ extensionapproach, in which a similar region of different length in ahomologue is used to extend the framework, can result in a moreaccurate model. If known homologues comprise more than one relatedgroup of proteins and they are both distantly related to theunknown, then alignment of the sequence to be modelled witheach group of homologues facilitates identification of structurallyconserved regions of the unknown and leads to an improved model.Models have root mean square differences (r.m.s.d.s) with thestructures defined by X-ray analysis of between 0.73 and 1.56Å for all C atoms, for seven of the eight models. Forthe model of mucor pepsin, where the closest homologue has 33%sequence identity and 20% of the residues are in structurallyvariable regions, the r.m.s.d. for the framework region is 1.71Å and the r.m.s.d. for all C atoms is 3.47 Â.     

Disulfide stabilization of antibody Fv: computer predictions and experimental evaluation

Using molecular modeling technology we have recently identifiedpositions in conserved framework regions of Fvs which can beused to stabilize antibody Fvs by an interchain disulfide bondengineered in between the structurally conserved framework positionsof the variable domains of heavy (V_H) and light (V_L) immunoglobulinchains (disulfide-stabilized Fv; dsFv). The computer model indicatedthe existence of other potential sites in the framework regionsthat might be suitable for disulfide bond formation betweenV_H and V_L. The possibility of obtaining dsFvs using these positionsis evaluated here experimentally by constructing dsFv immunotoxinsin which the Fv moiety is fused to a truncated form of Pseudomonasexotoxin. We analyzed the extent of dsFv formation and the activityof the resulting dsFv immunotoxins, and compared various dsFvmolecules with the scFv immunotoxin. Our results demonstratethat position H44-L105 is the only one which gives high productionyields of active dsFv. All other positions gave either low yieldsand activity or completely failed to produce active dsFv. Withone exception, the formation and activities of the dsFvs correspondedto the C-C distance between the VH and VL positions, with anoptimal distance of 5.7 Å producing the best dsFv. Distancesof 6.0–6.9 Å resulted in a' low yield of proteinthat was still capable of binding antigen, whereas distances>7.0 Å resulted in molecules in which dsFv formationwas not obtained.     

Structural basis for the extreme thermostability of D-glyceraldehyde-3-phosphate dehydrogenase from Thermotoga maritima: analysis based on homology modelling

D-Glyceraldehyde-3-phosphate dehydrogenase (GAPDH) from a hyperthermophiliceubacterium, Thermotoga maritima, is remarkably heat stable(T_m = 109°C). In this work, we have applied homology modellingto predict the 3-D structure of Th.maritima GAPDH to revealthe structural basis of thermostability. Three known GAPDH structureswere used as reference proteins. First, the rough model of onesubunit was constructed using the identified structurally conservedand variable regions of the reference proteins. The holoenzymewas assembled from four subunits and the NAD molecules. Thestructure was refined by energy minimization and molecular dynamicssimulated annealing. No errors were detected in the refinedmodel using the 3-D profile method. The model was compared withthe structure of Bacillus stearothermophilus GAPDH to identifystructural details underlying the increased thermostability.In all, 12 extra ion pairs per subunit were found at the proteinsurface. This seems to be the most important factor responsiblefor thermostability. Differences in the non-specific interactions,including hydration effects, were also found. Minor changeswere detected in the secondary structure. The model predictsthat a slight increase in a-helical propensities and helix-dipoleinteractions also contribute to increased stability, but toa lesser degree.     

Homology model of thyroxine binding globulin and elucidation of the thyroid hormone binding site

The tertiary structure of thyroxine binding globulin (TBG) hasbeen modelled on the basis of its close homology to ₁-antitrypsin,the archetype of the serine protease inhibitor (serpin) superfamily.Energy minimization was applied to the model to refine the structurefurther. The putative thyroid hormone binding region suggestedin previous labelling studies was found to exist within a ß-barrelstructure of complementary dimensions to the thyroid hormones.The model also revealed that the binding cleft provides thehydrophobic environment and specific ionic interaction sitesdeemed important for thyroid hormone binding. The model is ingood agreement with evidence derived from previously reportedT₃ and T₄ binding, stability and isoelectric focussing studiesof TBG and TBG variants. Finally, T₄ analogue and drug bindingstudies have enabled us to postulate the orientation and mannerof hormone binding to TBG. This may prove to be of assistancein the development of potent and specific, non-thyroidal ligandsand also aid in the understanding of physiological thyroid hormonebinding interactions.     

The expression of bovine microsomal cytochrome b5 in Escherichia coli and a study of the solution structure and stability of variant proteins

The DNA sequence of bovine microsomal cytochrome b₅ has beenamplified from a liver cDNA library using a polymerase chainreaction. The amplified cDNA when cloned into plasmids thatsupport the high-level production of cytochrome b_s in E.colileads to protein overexpression and results in cell coloniesbearing a strong red colouration. Using cassette mutagenesis,truncated versions of the cytochrome b₅ cDNA have been madethat encode the first 90 amino acid residues (Ala1-Lys90), thefirst 104 amino acids (Ala1-Ser104) and the complete protein(Ala1-Asnl33). The location of the overexpressed cytochromebs within prokaryotic cells is dependent on the overall lengthof the protein. Expression of the Ala-Lys90 and Alal-SerlO4variants leads to a location in the cytoplasmic phase of thebacteria whereas the whole protein, Alal-Asnl33, is found withinthe bacterial membrane fraction. The last 30 residues of cytochromebs therefore contain all of the necessary information to insertthe protein into E.coli membranes. The solubility of the Alal-SerlO4variant permits the solution structure and stability of thisprotein to be measured using 1- and 2-D ¹HNMR methods and electronicspectroscopy. 1-D NMR studies show that the chemical shiftsof the haem and haem ligand resonances of the Alal - Ser 104variant exhibit only very slight perturbations to their magneticmicroenvlronments when compared with the tryptic fragment offerricytochrome b₅. These results indicate an arrangement ofresidues in the haem pocket that is very similar in both theAlal-Ser 104 variant and the tryptic fragment and by 2-D NMRit is shown that this similarity extends to the conformationsof the poly peptide backbone and side chains. Electronic spectroscopyof this variant shows absorbance maxima for the Soret peaksat 423 run (reduced) and 413 nm (oxidized). From absorbancespectra the relative thermal stabilities of the Alal-Ser 104variant and the tryptic fragment were measured. In the oxidizedstate the Ala1 - Ser104 variant denatures in a single cooperativetransition with a midpoint temperature (T_m of 73°C thatis significantly higher than that of ‘tryptic’ ferricytochromebs. The reduced form of the protein shows increased transitiontemperatures (T_m 78°C) reflected in the values of H_m, S_mand (G) of 420 kj/mol, 1096 J/mol/K and 12.38 kj/mol respectively,estimated for this variant. The increased stability of the Alal-SerlO4variant and other recombinant forms of cytochrome b_s is correlatedwith the presence of additional residues at the N- and C-termini.The subtle differences in reactivity, stability and targetingbetween variant forms of cytochrome bs and the tryptic fragmentare discussed in terms of the overall structure of the protein.     

Simulation of a complex protein structural change: the T {leftrightarrow} R transition in the insulin hexamer

The T R transition in the insulin hexamer is an outstandingmodel for protein structural changes in terms of its extentand complexity: the limiting structures T₆, T₃R₃ and R₆ havebeen defined by X-ray crystallography. The transition occurscooperatively within trimers. It involves displacements of >30Å and a secondary structural rearrangement of 15% of thepeptide chain between extended and helical conformations. Experimentaldata for the transition are plentiful. Theoretical methods tosimulate pathways without constraints would never succeed withsuch substantial transitions. We have developed two approaches,targeted energy minimization (TEM) and targeted molecular dynamics(TMD). Previously successful in simulating the T R transitionof the insulin monomer, these procedures are also shown hereto be effective in the hexamer. With TMD, more conformationalspace is explored and pathways are found at 500 kJ/mol lowerenergy than with TEM. Because the atoms have to meet distanceconstraints in sum rather than individually, a high degree ofconformational freedom and independence. is implied. T₆ T₃R₃and T₃R₃ T₆ pathways do not coincide because the transformationis directed. One subunit enters a dead end pathway in one directionof the TMD simulation, which shows that constraint and freedomare critically balanced. The ensemble of productive pathwaysrepresents a plausible corridor for the transition. A videodisplay of the transformations is available     

The de novo protein with grafted biological function: transferring of interferon blast-transforming activity to albebetin

The de novo protein albebetin has been designed recently toform a predetermined tertiary fold that has not yet been observedin natural proteins. An eight amino acid fragment (131–138)of human interferon ₂ carrying the blasttransforming activityof the protein was attached to the N-terminus of albebetin nextto its initiatory methionine residue. The gene of chimeric proteinwas expressed in a wheat germ cell-free translation system andsynthesized protein was tested for its compactness and stability.Its ability for receptor binding was also studied. We have shownthat albebetin with attached octapeptide is practically as compactas natural proteins of corresponding molecular weight and possesseshigh stability toward the urea-induced unfolding. It binds murinethymocyte receptor at a high affinity and activates the thymocyteblast transformation efficiently at a concentration of 10^-11M.     

Hyperthermostable mutants of Bacillus licheniformis {alpha}-amylase: multiple amino acid replacements and molecular modelling

We have identified previously two critical positions for thethermostability of the highly thermostable -amylase from Bacilluslicheniformis. We have now introduced all 19 possible aminoacid residues to these two positions, His 133 and Ala209. Themost favourable substitutions were to Ile and Val, respectively,which both increased the half-life of the enzyme at 80°Cby a factor of 3. At both positions a stabilizing effect ofhydrophobic residues was observed, although only in the caseof position 133 could a clear correlation be drawn between thehydrophobicity of the inserted amino acid and the gain in proteinstability. The construction of double mutants showed a cumulativeeffect of the most favourable and/or deleterious substitutions.Computer modelling was used to generate a 3-D structure of thewild-type protein and to model substitutions at position 209,which lies in the conserved (/ß)₈ barrel domain of-amylase; Ala209 would be located at the beginning of the thirdhelix of the barrel, in the bottom of a small cavity facingthe fourth helix. The model suggests that replacement by, forexample, a valine could fill this cavity and therefore increaseintra- and interhelical compactness and hydrophobic interactions.     

Investigation of the solution structure of chymotrypsin inhibitor 2 using molecular dynamics: comparison to X-ray crystallographic and NMR data

The native solution structure and dynamics of chymotrypsin inhibitor2 (CI2) have been studied using a long (5.3 ns) molecular dynamics(MD) simulation without any imposed restraints. The majorityof the experimentally observed spin–spin coupling constants,short– and long–range nuclear Overhauser effect(NOE) cross peaks and the amide hydrogen exchange behavior werereproduced by the MD simulation. This good correspondence suggeststhat the major structural features of the protein during thesimulation are representative of the true protein structurein solution. Two water molecules formed hydrogen bond bridgesbetween ß₂ and ß₃, in agreement with X–raycrystallographic data and a recent reassessment of the solutionstructure using time averaged NMR restraints during MD refinement.The active–site loop of the protein displayed the greateststructural changes and the highest mobility. When this loopregion was excluded, the average C r.m.s. deviation of the simulatedsolution structures from the crystal structure was 1.5 from0.5 to 5 3 ns. There is structural heterogeneity in particularregions of the NMR–derived solution structures, whichcould be a result of imprecision or true internal motion. Astudy of the distribution of mobility through the protein allowsus to distinguish between these two alternatives. In particular,deviations in the active–site loop appear to be a resultof heightened mobility, which is also supported by good correspondencebetween calculated and experimental S² N–H order parameters.On the other hand, other ill–defined regions of the NMR-derivedstructures are well defined in the simulation and are probablythe result of a lack of structural restraints (i.e. NOEs), asopposed to reflecting the true mobility.     

Estimating the twist of {beta}-strands embedded within a regular parallel {beta}-barrel structure

The parallel ß-barrel is a recurrent structural motiffound in a large variety of different enzymes belonging to thefamily of /ß-proteins. It has been shown previouslythat the hyperboloid can be considered as a scaffold describingthe parallel ß-barrel structure. To assess restraintson ß-strand twist imposed by a given scaffold geometry,the notion of scaffold twist, T_s, is introduced. From T_s, theß-strand twist (Tw_ß) expected for a givenscaffold geometry can be derived and it is verified that thiscomputed twist can be used to identify ß-barrels characterizedby good hydrogen bonding. It is noted that Tw_ß isonly slightly affected for ß-barrels differing inthe number (N) of ß-strands, suggesting that restraintson main-chain conformation of ß-strands are not likelyto account for the N = 8 invariability observed in natural parallelß-barrels thereby strengthening previous work rationalizingthis constancy.     

An 8-fold {beta}{alpha} barrel protein with redundant folding possibilities

Protein sequences containing redundant segments of secondarystructure at both termini have the choice a priori of foldinginto several possible circularly permuted variants of the wild-typetertiary structure. To test this hypothesis the gene of phosphoribosylanthranilate isomerase from yeast, which is a single-domain8-fold ß barrel protein, was modified to produce a10-fold ß homologue in Escherichia coli. It containeda duplicate of the two C-terminal ß units of supersecondarystructure fused to its N-terminus. Most of the protein was recoveredfrom the insoluble fraction of disrupted cells by dissolutionin guanidinium chloride solutions and refolding. Pristine proteinwas purified from the soluble fraction. The purified (ß)₁₀proteins were enzymically almost fully active. Absorbance, fluorescenceand circular dichroism spectra as well as the reversible unfoldingbehaviour of both proteins were also very similar to the propertiesof the original (ß)₈ protein. Digestion with endopeptidasesconverted both the pristine and the refolded (ß)₁₀variant to the same large fragment that had the N-terminal sequenceand mol. wt of the wild-type ß)₈ protein. The datasuggest that the folding of the (ß)₁₀ variant is controlledthermodynamically both in vivo and in vitro.     

Functional roles and subsite locations of Leu177, Trp178 and Asn182 of Aspergillus awamori glucoamylase determined by site-directed mutagenesis

Fungal glucoamylases contain four conserved regions. One regionfrom the Aspergillus niger enzyme contains three key carboxylicacid residues, the general acid catalytic group, Glu179, alongwith Asp176 and Glu180. Three site-directed mutations, Leu177– His, Trp178 – Arg and Asn182 – Ala, wereconstructed near these acidic groups to reveal the functionof other conserved residues in this region. Leu177 and Trp178are strictly conserved among fungal glucoamylases, while anamide, predominantly Asn, always occurs at position 182. Substitutionsof Leu177 or Trp178 cause significant decreases in k_cat withthe substrates tested. Similar increases in activation energiesobtained with Leu177 – His with both -(1,4)- and -(1,6)-linkedsubstrates indicate Leu177 is located in subsite 1. K_M valuesobtained with the Trp178 – Arg mutation increase for an-(1,6)-linked substrate, but not for -(1,4)-linked substrates.Calculated differences in activation energy between substratesindicate Trp178 interacts specifically with subsite 2. The Asn182 Ala mutation did not change k_cat or K_M values, indicating thatAsn182 is not crucial for activity. These results support amechanism for glucoamylase catalytic activity consisting ofa fast substrate binding step followed by a conformational changeat subsite 1 to stabilize the transition state complex.