RATES OF OXIDATION OF PHENOLS BY COMPOUND U OF
Transcription
RATES OF OXIDATION OF PHENOLS BY COMPOUND U OF
CHAPTER 4 RATES OF OXIDATION OF PHENOLS BY COMPOUND U OF HORSERADISH PEROXIDASE AND LACTOPEROXIDASE AND THEIR DEPENDENCE ON THE REDOX POTENTIALS 4.1 Introduction Oxidation of para substituted phenols by horseradish peroxidase compound II (HRP-II) and Lactoperoxidase compound II (LPO-H) were studied using stopped flow technique. Apparent second order rate constants (kapp) of the reactions of the oxidisable substrates were determined. In the present study, we have compared the kinetics of oxidation of phenols by HRP-II and LPO-II, with the redox potentials of the substrates. Reorganisation energy of electron-transfer in phenols was estimated from the variation of second order rate constants with the thermodynamic driving force. Heme peroxidases are widely distributed in the living matter [1-3]. They catalyse oxidation of broad variety of organic as well as inorganic substrates (AH2) by hydrogen peroxide or alkylperoxides, usually but not always, via free-radical intermediates represented by following equations [1], E + H20 2 -> E - 1 + AH2 E —I + H 20 -> E - II + AH2 2AH. E - II + AH. E + AH. + H20 —»■ Products, 59 (1) (2) (3) (4) in which E, E-I, E-II represent native peroxidase (HRP/LPO) and its two spectros copically and kinetically distinct intermediates, peroxidase-I and peroxidase-II respect ively. Among the oxidisable aromatic substrates, phenols are known to react via a free radical intermediate mechanism depicted [4-14]. Substituted phenols have been shown to react with HRP -II, in their protonated form and the electron donation to the ferryl group, (Fe™ = 0), of HRP -II, is accompanied by a concomitant proton donation [5-7], Reactions of phenols are chemically controlled bimolecular reactions with rapid pre equilibrium of the reactants forming a loose precursor complex, which is characterised by large Michaelis-Menton (Km) constant, particularly at sufficiently high substrate concentration [5,6,12,15], This is followed by a rate determining redox step [4-14], Dunford and Adeniran [7] showed that the rates of oxidation of phenols followed Hammett’s rules. Kinetic and molecular orbital studies showed that the rate of oxidation also correlated well with the highest occupied molecular orbital energy levels of phenols [13,14] and showed that the rate of oxidation by HRP-II depends on the ease of oxidation [7,13,15], Mechanism of electron transfer, however, not fully understood and also such studies on LPO -II are very limited [16], HRP-C and LPO were purified by the procedures re[ported in the literature [16,17], with Rzs 3.2 and 0.94 respectively. 4.2 Results and Discussions : > Figure 4.1 shows a plot of kob, vs [S] for HRP-II as well as LPO-H reactions with phydroxy-benzoic acid as the substrate. It is seen that up to a substrate concentration of »350 pM, the k ^ values vary linearly with [S], Similar behaviours of kobs with [S] were observed for the reactions of all the other phenols studied here. This reaction can be expressed as, HRPr = 0 +S -» [ HRPFe^ = O - S] -» HRPFem + products (5) ki, k_i kET which gives the relation between kob, and [S] as 60 [S] OiM) Figure 4. 1 : Plot of kobsvs substrate (p-hydroxy-benzoic acid) concentration at pH = 7.0, and at 23° C, for LPO-II and HRP-II. Solid lines are leasts square fit of the data to equation 7. kob, = (6) kET[S ]/K D+[S] where KD = [HRP-II][S] / [HRP-II][S] = k-1/ k, = K* is the dissociation constant (Michaelis constant) of the enzyme substrate complex. For a loose enzyme-substrate precursor complex, i.e.Ko » [S], a linear relationship, kobs ~ (kET / Kd) [S] « kapp [S] (7) is observed. The linearity in kobs vs [S] plots (figure 4.1) is therefore, due to Kd » [S]. Apparent second order rate constant, kapp, values were deduced from the kob* vs [S] plots by least squares fit to equation 7 and also deduced from the slope of the kot» vs [S] plots, agreed very well. For a large number of substituted phenols, one electron redox potentials E(PhO /PhOH) have been measured by pulse radiolysis and are available in the literature [21-23], Figure 4. 2 shows plot of lnkappvs E(PhO/PhOH) in Volts, the one electron redox potentials of the phenols used in the measurement. Essentially non linear but relatively smooth variation of lnkapp for the reactions of peroxidase-II (HRP-II/LPO-H) with the substrate redox potentials strongly suggests that the nature of interaction of phenols with both the enzymes seems to be very similar. Figure 4.2 shows that the lnkapp for phenols with electron donating substituents such as methyl, methoxy and chloro groups are larger in magnitude relative to electron withdrawing substituents. Dunford and Adeniran [7] observed that the second order rate constants o f the reactions of phenols with HRP-II followed Hammett equation (linear correlation), but the Okomoto-Brown plot of the same rate constants was non-linear [24],This was explained by a mechanism of phenol oxidation, in which the substrate simultaneously gives an electron and a proton to HRP- II. This mechanism was however, questioned on the basis that the Hammett coefficients used were in error [27], It was suggested that electron transfer is followed by proton loss by the substrate [27], The redox potentials of the substituted phenols 61 Oxidation Potential (v) Figure 4. 2 : Plot of log k.__ vs one electron oxidation potential ® rr of various p-substituted phenols for LPO II (O) and HRP II (A). The solid line drawn to highlight the non-linearity of the variation. however, satisfy linear Hammett correlation using Okamoto-Brown (a+) substituent constants [22,24-26]. Figure 4.2, therefore, represents Okamoto-Brown plot of both LPO-II and HRP-II reactions which are non-linear. The mechanism of oxidation of phenols occurs by Dunford mechanism. The reactivity of the enzyme towards substrate is related to the thermodynamic driving force. Since one electron redox potentials of the unstable organic radicals of the substrates are known [21-23], it is possible to estimate the reorganisation energy parameter for the electron transfer using Marcus treatment [2829], Thermodynamic driving force for reaction of peroxidase -II with the reducing substrate (equation 3) is the difference between the mid-point potentials of the peroxidase-II / peroxidase (HRP-II / HRP) or (LPO-II / LPO) and substrate radical / substrate (S**tT / SH) redox couple. AE = E (peroxidase-II / peroxidase) - E (S**H" / SH) (8) Mid-point potentials are defined as the potential at which the concentration of the reduced and the oxidised forms of the couple are equal [30], E(HRP-II/HRP = 0.903 V at pH = 7.6 has been reported by He at al. [31], but no such data is available for LPO-H/LPO couple. Figure 4.3 shows the variation of the rate of reduction of HRP-n on the thermodynamic driving force of the reactions of phenols. > The thermodynamic free energy of the electron transfer reaction (AG°) is equal to the -nFAE (n number of electrons transferred, F is the Faraday constant). The increase in lnkapp on increasing the thermodynamic force (AE) as in figure 4.3, therefore, indicates that the electron transfer rate (or activation energy) is predominantly regulated by the redox potential difference between the substrate and HRP-II and the reaction can be described by an “outer-sphere” mechanism [27,28,31]. This is also consistent with the observation by Dunford and others [5,6,12,15] that the phenol oxidation reactions are predominantly chemically controlled. According to Marcus treatment [28,29] of electron transfer reactions, the parabolic curve (figure 4.3) representing the dependence of the logarithm of the rate 62 18 16 - 14 - dde, - * c 12 - 10 - 8 - 6 i ----------------------1----------------------1----------------------1----------------------1---------------------- \ -0.3 -0.2 -0.1 0.0 0.1 0.2 0.3 E ( HRP II / HRP ) - E ( S ~ H+ / S H ) Figure 4.3 : Variation of rate of reduction of HRP II to HRP on the thermodynamic driving force of the reaction . Natural logarithm of electron transfer rate constant (In kapp) are plotted against AE. The solid curve calculated using parameters obtained by leasts square fit of the data to equation 11. (see Text) constant (IiiIcet) on the thermodynamic driving force (AE) is associated with the reorganisation energy X as given by kET = kET0 exp ( -AG* / RT ) where k ET° (9) is the rate of activationless electron transfer in the enzyme- substrate complex and AG* is the activation free energy, given by; AG* = X( 1-(FAEA.) f 4 (10) Combining equations 7, 9 and 10 to yield, lnkapp = lnkapp° - ( X-AE)274 kB X T (11) where kB is Boltzmann constant. The reorganisation energy X (in units of eV) is related to the internal nuclear, as well as solvent molecule, rearrangements that must occur prior to electron transfer between the donor and the acceptor atoms [28,29], The solid line in figure 4.3 shows the least squares fit to equation (11) (correlation coefficient, r2 = 0.85) using two variable parameters lnkapp0 and X. The values are X = 0.2± 0.1eV and lnkapp0 = 16.0 ±0.8. X values reported for typical electron transfer proteins are in the range of 0.1-1.75 eV [29], Relatively low value of 0.2 eV obtained here, may be due to electron transfer which occurs in a loose enzymesubstrate complex. The HRP structure shows that the heme edge is particularly oriented for formation of such a complex, which may be helpful to minimise the donoracceptor distance. It also reflects rigidity of the electron accepting moiety, the heme group. Figure 4 shows a plot for LPO-II reactions with the phenols. The similarity in the nature of variation of lnk*pp vs thermodynamic force indicates that the mechanism of electron in both these peroxidases is same. Here we have used the same E(HRPII/HRP) = 0.903 V at pH 7.6 to calculate the thermodynamic driving force as this quantity is not known. The values of the parameters estimated by the least squares fit to the equation 9 are, X = 0.09 ± 0.05 and lnv = 15.4 ± 0.8 and correlation coefficient r2 = 0.31. The reason for low correlation coefficient may be the E(LPOn/LPO) value used may be in error. Also the measurements need to be extended on 63 app E (LPO 117 LPO ) - E ( S ~H+ / SH ) Figure 4 .4 : Variation of rate of reduction of LPO II to LPO on the thermodynamic driving force of the reaction . Natural logarithm of electron transfer rate constant (In kaDD) are plotted against " H r 0.903 - v values of HRP I I I HRP. The solid curve calculated using parameters obtained by leasts square fit of the data to equation 11. (see Text) more reducing phenols. However, the increase in the electron transfer rate with increasing thermodynamic driving force is similar as in HRP-II. Considerably low reorganisation energy compared to HRP-II reactions may be that LPO with large molecular size [32] has heme moiety in very rigid [33] and deeply buried in the protein fold [34], 64 REFERENCES [1] Dunford, H, B a n d Stillman, J, S., (1976), Coord. Chem. Rev. 1 9 ,187. [2] Dunford, H, B., (1982), Adv. 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