Gap junction communication dynamics and bystander effects from ultrasoft X-rays.

Gap junctions provide a route for small molecules to pass directly between cells. Toxic species may spread through junctions into 'bystander' cells, which may be exploited in chemotherapy and radiotherapy. However, this may be prevented by junction closure, and therefore an understanding of the dose-dependency of inhibition of communication and bystander effects is important. Low-energy ionising radiation (ultrasoft X-rays) provides a tool for the study of bystander effects because the area of exposure may be carefully controlled, and thus target cells may be clearly defined. Loss of gap junction-mediated intercellular communication between irradiated cells was dose-dependent, indicating that closure of junctions is proportional to dose. Closure was associated with hyperphosphorylation of connexin43. Inhibition of communication occurred in bystander cells but was not proportional to dose. Inhibition of communication at higher radiation doses may restrict the spread of inhibitory factors, thus protecting bystander cells. The reduction in communication that takes place in bystander cells was dependent on cells being in physical contact, and not on the release of signalling factors into the medium.

Multiple conformations of the acylenzyme formed in the hydrolysis of methicillin by Citrobacter freundii beta-lactamase: a time-resolved FTIR spectroscopic study.

Time-resolved infrared difference spectroscopy has been used to show that the carbonyl group of the acylenzyme reaction intermediate in the Citrobacter freundii beta-lactamase-catalyzed hydrolysis of methicillin can assume at least four conformations. A single-turnover experiment shows that all four conformations decline during deacylation with essentially the same rate constant. The conformers are thus in exchange on the reaction time scale, assuming that deacylation takes place only from the conformation which is most strongly hydrogen bonded or from a more minor species not visible in these experiments. All conformers have the same (10 cm-1) narrow bandwidth compared with a model ethyl ester in deuterium oxide (37 cm-1) which shows that all conformers are well ordered relative to free solution. The polarity of the carbonyl group environment in the conformers varies from 'ether-like' to strongly hydrogen bonding (20 kJ/mol), presumably in the oxyanion hole of the enzyme. From the absorption intensities, it is estimated that the conformers are populated approximately proportional to the hydrogen bonding strength at the carbonyl oxygen. A change in the difference spectrum at 1628 cm-1 consistent with a perturbation (relaxation) of protein beta-sheet occurs slightly faster than deacylation. Consideration of chemical model reactions strongly suggests that neither enamine nor imine formation in the acyl group is a plausible explanation of the change seen at 1628 cm-1. A turnover reaction supports the above conclusions and shows that the conformational relaxation occurs as the substrate is exhausted and the acylenzymes decline. The observation of multiple conformers is discussed in relation to the poor specificity of methicillin as a substrate of this beta-lactamase and in terms of X-ray crystallographic structures of acylenzymes where multiple forms are not apparently observed (or modeled). Infrared spectroscopy has shown itself to be a useful method for assessment of the uniqueness of enzyme-substrate interactions in physiological turnover conditions as well as for determination of ordering, hydrogen bonding, and protein perturbation.

Hydrogen bonding and protein perturbation in beta-lactam acyl-enzymes of Streptococcus pneumoniae penicillin-binding protein PBP2x.

A soluble form of Streptococcus pneumoniae PBP2x, a molecular target of penicillin and cephalosporin antibiotics, has been expressed and purified. IR difference spectra of PBP2x acylated with benzylpenicillin, cloxacillin, cephalothin and ceftriaxone have been measured. The difference spectra show two main features. The ester carbonyl vibration of the acyl-enzyme is ascribed to a small band between 1710 and 1720 cm-1, whereas a much larger band at approx. 1640 cm-1 is ascribed to a perturbation in the structure of the enzyme, which occurs on acylation. The protein perturbation has been interpreted as occurring in beta-sheet. The acyl-enzyme formed with benzylpenicillin shows the lowest ester carbonyl vibration frequency, which is interpreted to mean that the carbonyl oxygen is the most strongly hydrogen-bonded in the oxyanion hole of the antibiotics studied. The semi-synthetic penicillin cloxacillin is apparently less well organized in the active site and shows two partially overlapping ester carbonyl bands. The penicillin acyl-enzyme has been shown to deacylate more slowly than that formed with cloxacillin. This demonstrates that the natural benzylpenicillin forms a more optimized and better-bonded acyl-enzyme and that this in turn leads to the stabilization of the acyl-enzyme required for effective action in the inhibition of PBP2x. The energetics of hydrogen bonding in the several acyl-enzymes is discussed and comparison is made with carbonyl absorption frequencies of model ethyl esters in a range of organic solvents. A comparison of hydrolytic deacylation with hydroxaminolysis for both chymotryspin and PBP2x leads to the conclusion that deacylation is uncatalysed.

Secondary structure of the C-terminal DNA-binding domain of the transcriptional activator NifA from Klebsiella pneumoniae: spectroscopic analyses.

The conformation of the C-terminal DNA-binding domain of the transcriptional activator NifA from Klebsiella pneumoniae has been probed by circular dichroism (CD), Fourier-transformed infrared (FT-IR), and nuclear magnetic resonance (NMR) spectroscopy in combination. Secondary structure prediction suggests that the C-terminal half of the domain contains three alpha-helices. The spectra show that the domain is folded in the absence of DNA and of the N-terminal and central domains of NifA. The three spectroscopic techniques suggest slightly different proportions of secondary structural elements but all suggest that it contains about 33% alpha-helix. These results are in agreement with a previous prediction suggesting that NifA contains a helix-turn-helix motif and with the amount of alpha-helix predicted. The environment of the aromatic residues was examined by CD and NMR spectroscopy, which suggest that one or both of the tryptophan residues are involved in the tertiary structure of the protein but that the tyrosine residue in the helix-turn-helix motif is solvent exposed and so available to bind to DNA. The thermal melting profiles and pH-dependent structural changes were also examined by CD spectroscopy. This technique indicates that at low pH there is an increase in the secondary structure and interactions contributing to the tertiary structure. Many of the acidic residues are predicted to be on a single helix, before the helix-turn-helix motif, which may therefore be important for maintaining the structure and function of the C-terminal peptide; alternatively, the N-terminal half of the domain may become more folded at low pH.

Conserved residues in the mechanism of the E. coli Class II FBP-aldolase.

The two classes of fructose-1,6-bisphosphate aldolase both catalyse the reversible cleavage of fructose 1,6-bisphosphate into dihydroxyacetone phosphate and glyceraldehyde 3-phosphate. The Class I aldolases use Schiff base formation as part of their catalytic mechanism, whereas the Class II enzymes are zinc-containing metalloproteins. The mechanism of the Class II enzymes is less well understood than their Class I counterparts. We have combined sequence alignments of the Class II family of enzymes with examination of the crystal structure of the enzyme to highlight potentially important aspartate and asparagine residues in the enzyme mechanism. Asp109, Asp144, Asp288, Asp290, Asp329 and Asn286 were targeted for site-directed mutagenesis and the resulting proteins purified and characterised by steady-state kinetics using either a coupled assay system to study the overall cleavage reaction or using the hexacyanoferrate (III) oxidation of the enzyme bound intermediate carbanion to investigate partial reactions. The results showed only minor changes in the kinetic parameters for the Asp144, Asp288, Asp290 and Asp329 mutants, suggesting that these residues play only minor or indirect roles in catalysis. By contrast, mutation of Asp109 or Asn286 caused 3000-fold and 8000-fold decreases in the kcat of the reaction, respectively. Coupled with the kinetics measured for the partial reactions the results clearly demonstrate a role for Asn286 in catalysis and in binding the ketonic end of the substrate. Fourier transform infra-red spectroscopy of the wild-type and mutant enzymes has further delineated the role of Asp109 as being critically involved in the polarisation of the carbonyl group of glyceraldehyde 3-phosphate.

Novel natural product 5,5-trans-lactone inhibitors of human alpha-thrombin: mechanism of action and structural studies.

High-throughput screening of methanolic extracts from the leaves of the plant Lantana camara identified potent inhibitors of human alpha-thrombin, which were shown to be 5,5-trans-fused cyclic lactone euphane triterpenes [O'Neill et al. (1998) J. Nat. Prod. (submitted for publication)]. Proflavin displacement studies showed the inhibitors to bind at the active site of alpha-thrombin and alpha-chymotrypsin. Kinetic analysis of alpha-thrombin showed tight-binding reversible competitive inhibition by both compounds, named GR133487 and GR133686, with respective kon values at pH 8.4 of 1.7 x 10(6) s-1 M-1 and 4.6 x 10(6) s-1 M-1. Electrospray ionization mass spectrometry of thrombin/inhibitor complexes showed the tight-bound species to be covalently attached, suggesting acyl-enzyme formation by reaction of the active-site Ser195 with the trans-lactone carbonyl. X-ray crystal structures of alpha-thrombin/GR133686 (3.0 A resolution) and alpha-thrombin/GR133487 (2.2 A resolution) complexes showed continuous electron density between Ser195 and the ring-opened lactone carbonyl, demonstrating acyl-enzyme formation. Turnover of inhibitor by alpha-thrombin was negligible and mass spectrometry of isolated complexes showed that reversal of inhibition occurs by reformation of the trans-lactone from the acyl-enzyme. The catalytic triad appears undisrupted and the inhibitor carbonyl occupies the oxyanion hole, suggesting the observed lack of turnover is due to exclusion of water for deacylation. The acyl-enzyme inhibitor hydroxyl is properly positioned for nucleophilic attack on the ester carbonyl and therefore relactonization; furthermore, the higher resolution structure of alpha-thrombin/GR133487 shows this hydroxyl to be effectively superimposable with the recently proposed deacylating water for peptide substrate hydrolysis [Wilmouth, R. C., et al. (1997) Nat. Struct.Biol. 4, 456-462], suggesting the alpha-thrombin/GR133487 complex may be a good model for this reaction.

Kinetic aspects of ATP amplification reactions.

The accurate determination of very low concentrations of ATP is important in many areas of pure and applied biochemistry, particularly hygiene monitoring in the food industry. Two mathematical models have been used to show that a luciferase-linked ATP recycling enzyme assay can determine sample ATP concentration from the time taken for observed bioluminescence to reach half its maximum value. Such a time-based assay has the potential to detect very low ATP concentrations in less than 10 min without the need for a sensitive photometer.

Modulation of firefly luciferase bioluminescence at bioelectrochemical interfaces.

This paper describes a method by which the activity of an immobilized enzyme can be modulated electrochemically at an electrode. The particular example studied, involving the enzyme firefly luciferase being immobilized in a gelatin film of thickness <1 µm, provides a useful model system since changes in the catalytic activity can be measured instantaneously through the natural bioluminescent emission. Using this biointerfacial arrangement, we have been able to demonstrate the reversible switching off and on of the enzyme's activity. Through a series of mechanistic studies, we have been able to determine that the bioluminescence response is modulated (on long time scales) as a consequence of the electrochemical depletion of protons at the electrode interface resulting in a local increase in pH.

Resonance Raman spectroscopy of 4-thiothymidine and oligodeoxynucleotides containing this base both free in solution and bound to the restriction endonuclease EcoRV.

The resonance Raman spectra of 4-thiothymidine [4ST] have been recorded (a) in the free deoxynucleoside form, (b) when incorporated into the single stranded oligodeoxynucleotide d(AG[4ST]-TC), and (c) within the double-stranded self-complementary dodecamer d(GACGA[4ST]ATCGTC). Vibrational mode assignments of almost all the major Raman bands observed in each spectra have been made, mainly by comparison with the published assignments of related nucleosides and nucleotides. Differences between the spectra were observed, particularly when [4ST] and d(AG[4ST]TC) were compared to d(GACGA[4ST]ATCGTC). This is explained in terms of the variations in structure between single-and double-stranded DNA. Good quality spectra were obtained at nucleotide/oligonucleotide concentrations of between 100 and 500 microM and this coupled with an apparatus that uses small volumes (100 microL) allowed measurement of the spectrum of d(GACGA[4ST]ATCGTC) bound to the EcoRV endonuclease. This well characterised nuclease, for which crystal structures are available, recognizes d(GATAT) sequences. When this is replaced with d(GA[4ST]ATC), a poor substrate results but turnover can be prevented during data accumulation by omission of the essential cation Mg2+. Large shifts in several of the Raman bands were observed, and these have been related to the environment of the [4ST] base in the protein-bound oligonucleotide as deduced from the crystal structure. The wavenumber for the C = S stretch vibration in free d(GACGA[4ST]ATCGTC) has been used to calculate the strength of the Watson-Crick hydrogen bond between the sulphur atom in [4ST] and the 6-NH2 group on its partner dA. On binding to the enzyme, the shift in the wavenumber of the C = S stretch indicates this Watson-Crick hydrogen bond is weakened, in good agreement with X-ray structures. The advantage of using [4ST] as a resonance Raman probe is that it absorbs at 340 nm, a wavelength where other nucleic acid and protein absorbance is minimal. Thus the spectra obtained are very simple and consist of signals that arise predominantly from the thiobase alone, and this facilitates data interpretation.

Electroporation-induced damage in mammalian cell DNA.

Electroporation induced damage in the DNA of HL60 cells has been investigated by alkaline elution techniques. DNA damage is minimised by reducing the total charge applied (i.e., voltage x capacitance). Reduction of either of these electrical parameters, however, compromises the induced permeability of the cells to small molecules. The data presented concerning the effects of voltage and capacitance on DNA damage and the permeability of cells can be used to specify optimum conditions for electroporation in which DNA damage is minimised. The duration for which the current is applied can be seen to have a significant effect on the level of DNA damage. A modest temperature rise may occur when an electric charge is passed through electroporation buffer, but this event alone does not induce DNA damage in cells. The effect of voltage upon the permeability of HL60 cells to fluorescent-labelled molecules of varying molecular weight is reported.

A critical analysis of the use of radiation inactivation to measure the mass of protein.

Measurements are presented of the radiation inactivation of four enzymes exposed to a 6 MeV proton beam. It has long been thought that the measurement of the susceptibility of an enzyme to ionizing radiation can be used to determine its molecular mass. Results are frequently interpreted using the empirical analysis of Kempner and Macey (Biochim. Biophys. Acta 163, 188-203, 1963). We examine this analysis and discuss the validity and limitations of the assumptions on which it is based. Our results indicate that the specific biochemical properties of each enzyme make a significant contribution to its radiation sensitivity.

A stopped-flow apparatus for infrared spectroscopy of aqueous solutions.

IR spectroscopy has been widely applied in the study of photo-activated biological processes such as photosynthesis, but has not been applied to the study of reacting systems which require rapid mixing of aqueous solutions. This has been due in part to the high pressure needed to make an aqueous solution flow rapidly through the 50 microns optical pathlength between the plates in an IR cuvette suitable for use with 2H2O and the high viscosity of the concentrated protein solutions required to generate measurable IR signals. An apparatus, based largely on conventional stopped-flow technology, is described which achieves mixing well within the time-resolved performance (approximately 40 ms) of modern Fourier-transform IR (FTIR) spectrometers, since the dead time of the mixing device is approximately 15 ms. It has proved possible to achieve efficient mixing by using a simple six-jet mixing device. This is probably at least in part because of the high back pressure which develops when aqueous fluid is passed rapidly through the short pathlength of the cuvette and which promotes turbulent flow. Several examples of measurements of the deacylation of acylchymotrypsins are provided which demonstrate the operation of the apparatus in conjunction with a spectrometer capable of scanning at four scans/s. For cinnamoyl-chymotrypsin, isotope-edited spectra have been obtained which show somewhat lower resolution than is achieved by conventional scanning methods, since some smoothing has to be applied to the spectra. Difference spectra of the acylation of chymotrypsin by glycylglycine p-nitrophenyl ester have been obtained by averaging ten stopped-flow shots and show good signal-to-noise ratio without smoothing. It is predicted that this apparatus is likely to find a variety of applications in the study of enzyme-catalysed reactions, since the spectra are relatively rich in structural information, and isotope editing greatly enhances the interpretability of the spectra.

Analysis of hydrogen bonding in enzyme-substrate complexes of chloramphenicol acetyltransferase by infrared spectroscopy and site-directed mutagenesis.

Chloramphenicol acetyltransferase (CAT) reversibly transfers an acetyl group between CoA and the 3-hydroxyl of either chloramphenicol (Cm) or 1-acetylchloramphenicol (1AcCm). The products of the forward reactions, 3-acetylchloramphenicol (3-AcCm) and 1,3-diacetylchloramphenicol (1,3Ac2-Cm), are the substrates for the reverse reaction. The role of the 3-acetyl carbonyl group in the binding of the substrates 3AcCm and 1,3Ac2Cm to CAT has been investigated using infrared spectroscopy. Comparison of difference spectra (3-[12C = O]acetyl- minus 3-[13C = O]acetyl-) obtained for the binary complexes of 3AcCm with wild-type CAT, and with a variant wherein serine-148 is replaced by alanine (S148A), reveals a large (9 cm-1) down frequency shift for the 3-acetyl carbonyl stretch in the wild-type complex, indicative of a hydrogen bond between this carbonyl and the hydroxyl group of Ser-148. The carbonyl bandwidth in the wild-type complex is reduced by 33% compared to that for the complex with S148A, indicating restriction of carbonyl mobility and dispersion in the former, an observation consistent with the proposed hydrogen bond between the ester carbonyl and the hydroxyl of Ser-148. Repetition of the experiment using 1,3Ac2Cm as the ligand reveals a frequency shift of only 3 cm-1 between wild-type and S148A complexes, indicating only a small change in the strength of carbonyl interaction.(ABSTRACT TRUNCATED AT 250 WORDS)

The kinetics and mechanism of repair of UV induced DNA damage in mammalian cells. The use of 'caged' nucleotides and electroporation to study short time course events in DNA repair.

Using 'caged' DNA break trapping agents as well as the equivalent uncaged reagents and an automated apparatus, we have measured time courses of incorporation of radiolabelled nucleotides into HL60 cellular DNA in the early stages after 248 UV laser damage. These time courses show two distinctive phases, one between 0 and 120 seconds and another after 120 secs following damage. The first phase consists of a transient which shows a rapid initial incorporation of radiolabel followed by a sharp fall in incorporated label. This occurs with TTP as well as ddATP, which suggests that an excision activity which results in removal of recently incorporated bases is not solely provoked by the incorporation of an unnatural base, but also by the incorporation of an incorrectly paired base in a phase of what may be low fidelity repair. The second phase consists of a more steady state of incorporation. Both phases are dose dependent and show higher incorporation at higher doses. The transient is most apparent at does which cause some lethality. It may represent a form of emergency or 'panic' repair where it seems that there may be an immediate effort to maintain strand continuity in the damaged DNA. Results of experiments with polymerase inhibitors suggest that a polymerase which is sensitive to aphidicholin and which shows some sensitivity to dideoxythymidine is active during the transient phase of repair. Since excision of newly incorporated radiolabel takes place very rapidly during the first phase this would imply that a polymerase with an associated proof-reading nuclease is active at this stage. Polymerases alpha, delta, and epsilon all have this property but delta and epsilon have a higher sensitivity to dideoxythymidine than does alpha. Since the transient burst phase shows significant inhibition by dideoxythymidine, it is more likely that delta or epsilon are active at this stage. The putative panic response discussed in relation to proof reading mechanisms in aminoacyl-tRNA and DNA synthesis.

Effect of specificity on ligand conformation in acyl-chymotrypsins.

I.r. difference spectroscopy combined with 13C and 18O double-isotope substitution was used to examine the ester acyl carbonyl stretching vibration of hydrocinnamoyl-chymotrypsin. A single acyl carbonyl stretching band was observed at 1731 cm-1. This contrasts with previous i.r. and resonance Raman spectroscopic studies of a number of trans-3-arylacryloyl-chymotrypsins which showed two acyl carbonyl stretching bands in the region of 1700 cm-1, which were proposed to represent productive and non-productive conformations of the acyl-enzyme. The single acyl carbonyl band for hydrocinnamoyl-chymotrypsin suggests only a single conformation, and the comparatively high frequency of this band implies little or no hydrogen-bonding to this carbonyl group. Enzymic hydrogen-bonding to the acyl carbonyl is believed to give bond polarization and thereby catalytic-rate acceleration. Thus, in view of the apparent lack of such hydrogen-bonding in hydrocinnamoyl-chymotrypsin, it should be the case that this acyl-chymotrypsin is less specific than trans-3-arylacryloyl-chymotrypsins, whereas the opposite is true. It is therefore proposed that there may be a productive acyl carbonyl population of lower stretching frequency for hydrocinnamoyl-chymotrypsin, but that this is too small to be discerned because of either a relatively high deacylation rate or an unfavourable conformational equilibrium. The single acyl carbonyl band for hydrocinnamoyl-chymotrypsin is significantly broader than those for trans-3-arylacryloyl-chymotrypsins, indicating that this group is more conformationally mobile and dispersed in the former. This can be correlated with the absence of acyl carbonyl hydrogen-bonding in hydrocinnamoyl-chymotrypsin, and with the much greater flexibility of the saturated hydrocinnamoyl group than unsaturated trans-3-arylacryloyl. This flexibility is presumably the reason why hydrocinnamoyl-chymotrypsin is more specific than trans-3-arylacryloyl-chymotrypsins. Resonance Raman spectroscopy is limited to the non-specific trans-3-arylacryloyl-chymotrypsins because of its chromophoric requirement, whereas i.r. may be used to examine non-chromophoric more specific acyl-enzymes such as hydrocinnamoyl-chymotrypsin. The results presented in this paper suggest that trans-3-arylacryloyl-chymotrypsins are atypical.

Kinetics and mechanism of DNA repair: an automated programmable apparatus for fast time-resolved studies of the repair of mammalian DNA after u.v. irradiation.

An automated apparatus, designed and constructed for use in fast time-resolved studies of mammalian DNA repair after u.v. irradiation, is described. The methodology makes use of caged DNA-break-trapping reagents, e.g. [alpha-32P]dideoxyadenosine triphosphate [see Meldrum, Shall, Trentham and Wharton (1990) Biochem J. 266, 885-890] and the apparatus incorporates excimer lasers both for the delivery of u.v. damage and for the photoactivation of the caged reagents. The design is based on a sample-changing turntable which permits the sequential irradiation and quenching of samples. A maximum of eight samples can be processed in a single experiment, the sequence of events being programmed on a microcomputer, which permits a very generalized experimental sequence. Pipettes for addition of cells, nucleotides and quenching agent are driven pneumatically. A pair of pneumatically operated platinum electrodes allows electroporation of cells for loading of negatively charged reagents prior to irradiation. The time resolution of the apparatus is dependent upon the experimental scheme used and can be very short (e.g. 1 ms) when caged reagents are used; a more usual period is 1 s for the shortest incubation.

The binding of amide substrate analogues to phospholipase A2. Studies by 13C-nuclear-magnetic-resonance and infrared spectroscopy.

(R)-(2-dodecanamidoisohexyl)phosphocholine (DAHPC), labelled with 13C at the amide carbonyl group, has been synthesized and its binding to bovine pancreatic phospholipase A2 (PLA2) studied by n.m.r. and i.r. spectroscopy. Two-dimensional 1H-n.m.r. spectra show that, in the presence of Ca2+, DAHPC binds to the active site of the enzyme in a similar manner to other phospholipid amide substrate analogues. The environment of the labelled carbonyl group has been investigated by a combination of 13C n.m.r. and difference-Fourier-transform i.r. spectroscopy. The carbonyl resonance shifts 3 p.p.m. downfield on the binding of DAHPC to PLA2. The carbonyl absorption frequency decreases by 14-18 cm-1, accompanied by a marked sharpening of the absorption band. These results indicate that the carbonyl bond undergoes significant polarization in the enzyme-ligand complex, facilitated by the enzyme-bound Ca2+ ion. This suggests that ground-state strain is likely to promote catalysis in the case of substrate binding. Simple calculations, based on the i.r. data, indicate that the carbonyl bond is weakened by 5-9 kJ.mol-1. This is the first report of observation of the amide vibration of a bound ligand against the strong background of protein amide vibrations.

Analysis and elimination of protein perturbation in infrared difference spectra of acyl-chymotrypsin ester carbonyl groups by using 13C isotopic substitution.

I.r. spectroscopy has been applied to the study of hydrogen-bonding of the unique ester carbonyl group of acylchymotrypsins in the oxyanion hole of the enzyme. This catalytic device provides electrophilic stabilization of negative charge in the transition states and tetrahedral intermediates along the reaction pathway. The use of 13C isotope substitution of the ester carbonyl group reinforces the previous observation [White & Wharton (1990) Biochem. J. 270, 627-637] that the ester carbonyl group is significantly polarized in the ground state by hydrogen bonding in the oxyanion hole. I.r. difference spectra of [carbonyl-12C]-minus [carbonyl-13C]-cinnamoyl-chymotrypsin as well as each of these acylenzymes minus free enzyme are reported. These spectra show that the contribution of protein perturbation (i.e. spectral features that arise from the enzyme which is distorted on acylation) in [carbonyl-12C]cinnamoyl-chymotrypsin minus free enzyme spectra is significant. The contribution of the perturbation components of the spectra is pH-dependent and can represent up to 50% of the total absorbance in the spectral region from 1690 to 1740 cm-1. Use of the isotopic difference method has allowed problems associated with protein perturbation to be eliminated. Similar difference spectra are presented for dihydrocinnamoyl-chymotrypsin. In this case the effect of perturbation is very marked and leads to the cancellation of the band assigned to the non-bonded conformation of the acyl group which has previously only been observed at higher pH. The isotopic difference method again proves reliable and shows that the frequency difference previously used to calculate the ground-state electronic strain induced by the oxyanion-hole catalytic device is not affected by the perturbation, although the amplitudes of the spectral features are different. A study of the deacylation of cinnamoyl-chymotrypsin in water and deuterium oxide using both u.v. and i.r. spectroscopies has confirmed that the use of deuterium oxide as solvent has no serious effect on the deacylation behaviour of the enzyme. I.r. bands assigned to nonproductive and productive conformers decline identically during deacylation, which shows that the conformers are in dynamic exchange on the reaction time-scale.