Improved Whitten−Rabinovitch Approximation for the Rice

Feb 15, 2007 - Jeong Hee Moon , So Hee Yoon and Myung Soo Kim. The Journal of ... Jeong Hee Moon , Sohee Yoon , Yong Jin Bae , Myung Soo Kim...
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J. Phys. Chem. B 2007, 111, 2747-2751

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Improved Whitten-Rabinovitch Approximation for the Rice-Ramsperger-Kassel-Marcus Calculation of Unimolecular Reaction Rate Constants for Proteins Meiling Sun,† Jeong Hee Moon,‡ and Myung Soo Kim*,† Department of Chemistry, Seoul National UniVersity, Seoul 151-742, Korea, and Korea Research Institute of Bioscience and Biotechnology, Daejon 305-806, Korea ReceiVed: October 2, 2006; In Final Form: January 16, 2007

The Whitten-Rabinovitch (WR) approximation used in the semi-classical calculation of the RiceRamsperger-Kassel-Marcus (RRKM) unimolecular reaction rate constant was improved for reliable application to protein reactions. The state sum data for the 10-mer of each amino acid calculated by the accurate Beyer-Swinehart (BS) algorithm were used to obtain the residue-specific correction functions (w). The correction functions were obtained down to a much lower internal energy range than reported in the original work, and the cubic, rather than quadratic, polynomial was used for data fitting. For a specified sequence of amino acid residues in a protein, an average was made over these functions to obtain the sequencespecific correction function to be used in the rate constant calculation. Reliability of the improved method was tested for dissociation of various peptides and proteins. Even at low internal energies corresponding to the RRKM rate constant as small as 0.1 s-1, the rate constant calculated by the present method differed from the accurate BS result by 60% only. In contrast, the result from the original WR calculation differed from the accurate result by a factor of 3000. Compared to the BS method, which is difficult to use for proteins, the main advantage of the present method is that the RRKM rate constant can be calculated instantly regardless of the protein mass.

I. Introduction In the study of a unimolecular reaction, it is often useful to have a rate constant evaluated theoretically. For a unimolecular reaction occurring under the microcanonical condition, the Rice-Ramsperger-Kassel-Marcus (RRKM) theory1-6 is widely used to estimate the statistically expected rate constant. The theoretical rate constant is useful not only for direct comparison with the experimental one but also for various other purposes. For example, RRKM calculation is done in the field of mass spectrometry7-9 as an aid for understanding the structure and dissociation dynamics of molecular ions, estimating their internal energy contents, etc. When the molecular rotation is ignored, the expression for a unimolecular reaction rate constant derived by the RRKM theory is as follows.

k)σ

Nq(E - E0) hF(E)

(1)

Here F(E) is the vibrational state density of the reactant at the internal energy E, E0 is the critical energy of the reaction, Nq(E - E0) is the vibrational state sum from 0 to E - E0 at the transition state (TS), h is the Planck constant, and σ is the reaction path degeneracy, which is usually 1 for reactions involving large molecules. Even though the expression for the RRKM rate constant looks deceptively simple, various difficulties are encountered in actual calculation. The parameters needed for a RRKM calculation * To whom correspondence should be addressed. Telephone: +82-2880-6652. Fax: +82-2-889-1568. E-mail: [email protected]. † Seoul National University. ‡ Korea Research Institute of Bioscience and Biotechnology.

are the critical energy, the complete vibrational frequency set for the reactant, and that at the TS geometry. The major difficulty arises from the fact that the parameters related to the TS, namely E0 and the frequencies at the TS, cannot be measured experimentally. The data obtained via quantum chemical calculations can be used when the TS can be found through computation. The less rigorous but more widely used approach is to treat these as adjustable parameters. It is wellknown that the RRKM rate constant remains nearly the same regardless of the changes in individual frequencies as long as the entropy of activation, ∆Sq, is kept the same.7,10-12 Hence, the RRKM calculation of the rate-energy relation is often treated as a two parameter (E0 and ∆Sq) problem. In this approach, the frequency set at the TS is obtained from the reactant set by adjusting some of the frequencies in the latter set such that the postulated value of ∆Sq results. The fact that reasonable estimates for E0 and ∆Sq are needed for reliable estimation of the rate constant is the main drawback of this approach. When one attempts a RRKM calculation for large biological molecules such as peptides and proteins, additional difficulties arise due to the very large number of degrees of freedom involved. One of these difficulties is that it is virtually impossible at the moment to obtain the complete set of reactant frequencies either via experiment or via computation. In our previous paper,13 we reported a systematic and efficient method to estimate the frequency set for a peptide or a protein with any amino acid sequence and presented its utility in a RRKM calculation. The method started with the vibrational frequency sets for twenty amino acids calculated at the density functional theory (DFT) level. Then, the frequencies disappearing upon peptide bond formation were deleted from each set to obtain the fictitious sets for an amino acid residue at the N- or

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Sun et al.

C-terminus or inside the chain. For a specified sequence of a protein, these residue frequencies were collected and the frequencies appearing upon peptide bond formation were added to obtain the complete set for the reactant. The frequencies appearing upon protonation of a protein were added as needed to handle the reaction of protonated proteins that are of great interest in the field of mass spectrometry.14-16 The method treated all the vibrations as harmonic and ignored anharmonicity. Also ignored was the fact that some modes are better treated as internal rotations rather than vibrations.1,5 Such simplifications and the estimation of the frequencies at the TS using the postulated value of ∆Sq adopted in this method are causes for uncertainty in the RRKM calculations. Once the frequency sets for the reactant and TS are provided, various methods can be used to calculate the vibrational state sum and density. Several approximate methods had been developed in early days of RRKM calculations such as the Whitten-Rabinovitch (WR) semi-classical approximation17 and the steepest descent method18 to name a few. Even though these methods are efficient, all of these provide erroneous results at low internal energy range.1 For example, Derrick et al.19 showed that the WR method overestimated the dissociation rate constant of a small protein by orders of magnitude in the low internal energy. Virtually all of these approximate methods became obsolete after the invention of an efficient direct counting algorithm by Beyer and Swinehart (BS algorithm).20 When we attempted the RRKM calculation for proteins with relative molecular masses (RMM) as large as 10 000 or larger using the BS algorithm, however, we found that several hours or even days of computation were needed. In this paper, we will present a modification of the WhittenRabinovitch method for proteins. Its reliability in RRKM calculation for proteins will be demonstrated by comparing with the results obtained by the BS algorithm. II. Method In the Whitten-Rabinovitch (WR) approximation,17 the following expression is used for the vibrational state sum as suggested by Rabinovitch and Diesen.21

N(E) )

(E + aEz)s

∏hνi

s!

(2)

Here E is the vibrational internal energy as before, Ez is the zero-point energy, s is the number of the vibrational degrees of freedom, and νi is the frequency of the ith vibrational mode. This expression differs from the original semi-classical expression suggested by Marcus and Rice2 in that the parameter a is regarded as a molecule-dependent function of the internal energy rather than a constant (a ) 1) in the latter expression. To reduce the molecule dependence in the calculation, Whitten and Rabinovitch suggested to use another function w defined as below.

w ) (1 - a)/β

(3)

s - 1 〈ν 〉 s 〈ν〉2

(4)

with 2

β)

By comparing with the state sums for various organic and inorganic molecules calculated by direct count, Whitten and Rabinovitch obtained the following expression for w.

w ) (5.00 + 2.730.5 + 3.51)-1 w ) exp(-2.41910.25)

0.1 <  < 1.0 (5) 1.0 e 

(6)

Here,  is the internal energy scaled with the zero-point energy.

 ) E/Ez

(7)

The expression for the state density is obtained from the derivative of eq 2 as follows.

F(E) )

(E + aEz)s-1 (s - 1)!



hνi

[1 - β(dwd )]

(8)

Because both the sum and density are expressed in explicit analytical forms, the rate constant is calculated instantly as the frequencies and E0 are provided. As has been mentioned already, the rate constant calculated by the WR method deviates significantly from the direct count result in the low internal energy range. It is well-known in the field of mass spectrometry that the critical energies for many dissociation reactions of peptide and protein ions are rather low.22-24 Such an ion may dissociate on the mass spectrometric time scale (1 µs to 1 s) even when the internal energy is only a few electronvolts above the critical energy. Because the zeropoint energy increases in proportion to the reactant mass, a few electronvolts of internal energy correspond to  less than 0.1, which is below the limit optimized by Whitten and Rabinovitch. Also to be mentioned is that the w data used to derive the functions in eqs 5 and 6 in the original work showed a significant scatter even at  larger than 0.1 because these were the values obtained for compounds with widely different structures.17 The corresponding scatter is expected to be smaller when only the data for peptides and proteins are taken into account. The method used to calculate the RRKM rate constant for proteins in this work is essentially the same as in the original WR method. The only difference is that the sequence-specific w function derived from peptide data is used in the present work. Details of the method are as follows. The state sum for a 10-mer, X10, of each amino acid was calculated with the BS algorithm as a function of  in the range  ) 0.0005-2. Then, the w data for each peptide were calculated using eqs 2-4. These were taken as the representative data for this amino acid residue because the w data obtained from higher polymers were essentially the same. These data were used to obtain the w function of the following form.

w ) (c31.5 + c2 + c10.5 + c0)-1

(9)

The first term in this function was added to achieve fits with the correlation coefficient better than 0.99999. Two improved WR methods, IWR′ and IWR, were developed and tested. In the IWR′ method, a universal w function for proteins was estimated by averaging the w functions of the 10-mers of twenty amino acids using the natural abundances25 of the amino acids as the weighting factors. In the IWR method, the ci parameters for each amino acid residue in a protein were collected and averaged term by term, for example, C3 ) 〈c3〉, to estimate the w function for this protein. Namely, the w function used in the latter method differed for proteins with different amino acid composition unlike in the former method. It will be shown in the next section that IWR is our method of choice. The function in eq 6 turned out to be an excellent fit to the w data at  > 1

Improved WR Approximation for Proteins

Figure 1. The w functions for the 10-mers of twenty amino acids obtained by comparing the vibrational state sums calculated by the BS algorithm with eq 2. The w functions for M10 and T10 are marked, which form the upper and lower boundaries of the data, respectively. Also drawn is the w function in the original Whitten-Rabinovitch approximation. The abscissa is the internal energy scaled by the zeropoint energy.

for all the cases investigated even though calculations above  ) 1 were hardly needed in practical cases. Details of the method to calculate a rate-energy relation for a protein reaction with the BS algorithm were explained in a previous report13 and will not be repeated here. For the improved Whitten-Rabinovitch (IWR) calculation, the array (c3, c2, c1, c0) for each amino acid residue has been stored in the software together with the residue frequencies. When the amino acid sequence of the reactant is specified, the residue frequencies are collected and the w function is calculated from the arrays. The frequencies at the TS are estimated from the reactant frequencies and ∆Sq, which is designated by a user as one of the input parameters of the software. These and the E0 value are used to calculate F(E) and Nq(E - E0) and finally k(E). III. Results and Discussion The inverse cubic fittings of the w data were made for the 10-mers of twenty amino acids as described in the previous section. The 0.001 e  e 1.0 ranges of the twenty w functions thus obtained are shown in Figure 1 together with the original w function drawn with eq 5. The w data at  > 1.0 are not shown because eq 6 is an excellent description in this range regardless of the peptides. Two w functions, namely those for the 10-mers of methionine (M10) and threonine (T10), are marked in the figure. As the internal energy decreases, the peptide w data begin to deviate more and more from eq 5. Deviation is the largest for M10, and it is the smallest for T10. The (c3, c2, c1, c0) arrays determined for the twenty 10-mers through curve fitting are listed in Table 1. Figure 2 compares the rate-energy relations for M10 calculated by various methods using an E0 of 0.5 eV and ∆Sq of 0 eu (1 eu ) 4.184 J K-1 mol-1). The zero-point energy for this peptide calculated with the reactant frequencies used in the rate calculation is 39.6 eV. Hence, the internal energy of 3.96 eV is equivalent to the scaled energy () of 0.1. The rate constant calculated with the BS algorithm at this energy is 1.48 × 106 sec-1, corresponding to the half-life of 0.48 µs. On the other hand, the rate constant calculated by the original WR method is 5.79 × 106 s-1, which is larger than the correct (BS) value by a factor of 3.9. Such a difference is understandable because the correct w value for M10 at this energy is 0.2121, which is a little larger than the 0.2052 calculated by eq 5. It is to be emphasized that  ) 0.1 was the lower limit for the internal energy in the derivation of the w function in the original work, that the discrepancy between the WR and BS rate constants is

J. Phys. Chem. B, Vol. 111, No. 10, 2007 2749

Figure 2. The rate-energy relations for M10 calculated by the BS (s), WR (- ‚ -), IWR′ (-O-), and IWR (----) methods using an E0 of 0.5 eV and a ∆Sq of 0 eu.

TABLE 1: List of the c Parameters Derived from the 10-mers of Twenty Amino Acids Ala(A) Cys(C) Asp(D) Glu(E) Phe(F) Gly(G) His(H) Ile(I) Lys(K) Leu(L) Met(M) Asn(N) Pro(P) Gln(Q) Arg(R) Ser(S) Thr(T) Val(V) Trp(W) Tyr(Y)

c3

c2

c1

c0

0.763603 0.831468 1.138528 1.329782 1.236776 1.095241 1.347598 0.919614 1.128924 1.039792 1.215631 1.262370 1.349337 1.222632 1.305170 1.067582 0.886543 0.881758 1.285702 1.222054

3.422871 3.203076 2.643839 2.226432 2.461058 2.802168 2.266191 3.068504 2.624142 2.839106 2.452458 2.378021 2.226658 2.460278 2.346235 2.816962 3.266588 3.171401 2.468111 2.492761

3.911022 4.014916 4.308187 4.641321 4.385026 4.215922 4.474229 4.184229 4.441859 4.299746 4.548003 4.448872 4.544044 4.463422 4.582904 4.217357 3.900925 4.115937 4.353988 4.348006

3.166518 3.201546 3.206942 3.068151 3.152760 3.150475 3.176003 3.044556 3.012481 3.024606 2.988617 3.149506 3.083142 3.080824 3.021681 3.166776 3.215289 3.068043 3.194517 3.185401

significant at this energy, and that the rate constant is quite large even at such a low internal energy. As expected from the larger deviation of the correct w data from eq 5 at lower energy as seen in Figure 1, the WR rate constant in Figure 2 differs more from the BS rate constant at lower internal energy. When an ion cyclotron resonance mass spectrometer is used, the dissociation of a protein ion occurring on the time scale as long as 10 s may be observed, even though canonical rate constants rather than microcanonical ones calculated in this work may be more appropriate in some cases. Hence, let us compare the rate constants at the internal energy corresponding to the BS rate constant of 0.1 s-1 from now on. In the present case, this occurs at 1.38 eV. At this energy, the WR rate constant is as large as 300 s-1, corresponding to a factor of 3000 difference from the correct result. It is evident that the original WR method cannot provide a reasonable estimate of a rate constant at  < 0.1, even though physically meaningful reactions may occur at such a low internal energy. To summarize, the WR method is rapid but inaccurate in the low-energy range and the BS method is accurate but slow in the high-energy range. A way to get out of this dilemma may be to calculate the rate-energy relations using both methods, the BS calculation in the low-energy range and the WR calculation over the entire energy range of interest, and use the two together. Certainly, a better way is to devise a unified method that is efficient and accurate at the same time, as attempted in the present work.

2750 J. Phys. Chem. B, Vol. 111, No. 10, 2007 Initially, we hoped to achieve the above goal by using a universal w function that could be used for proteins with any sequence. The IWR′ method described in the previous section was devised for this purpose. The rate-energy relations calculated by the IWR′ method were in excellent agreement with the BS results for many peptides consisting of a variety of amino acid residues. In the IWR′ calculations, the largest error is expected for the peptides consisting of only one type of amino acid residue, especially M10 and T10. The rate-energy relation for M10 calculated by the IWR′ method with an E0 of 0.5 eV and a ∆Sq of 0 eu is shown in Figure 2 also. The IWR′ rate constant is in much better agreement with the BS result than is the WR result. At the internal energy of 1.38 eV chosen in the previous comparison, the IWR′ rate constant is 1.3 s-1, corresponding to a factor of 13 difference from the correct value. Namely, the difference factor of 3000 in the original WR method has been reduced to 13 in IWR′. We are not satisfied with the IWR′ method, however, because our aim is to develop a method that can reproduce a BS rate constant within a factor of 2. As has been mentioned already in the previous section, our method of choice (IWR) is to calculate a sequence-specific w function by averaging the w functions (w-1 actually) of the residues contained in a protein. The rate-energy relation for M10 calculated by IWR using the same E0 and ∆Sq values as before is also shown in Figure 2. Because all the residues are the same in M10, the sequence-specific w function evaluated from the residue functions is exactly the same as the residue function that was derived using the state sum calculated by the BS algorithm. Hence, one may expect to obtain an IWR rate constant that is essentially identical to the BS result. Even though the IWR and BS rate-energy relations in Figure 2 are nearly the same, a tiny difference can be observed. For example, the IWR rate constant at 1.38 eV is 0.160, namely 60% larger than the BS result. To see if the functional fitting of the w data is the source of such an error, we calculated the state density at 1.38 eV using the w function and compared it with the BS state density. The BS density turned out to be larger than the IWR density only by 0.2%, which is the fitting error for the state density. We also calculated the state sum at 0.88 eV, which is the internal energy at the TS. Here, the difference between the IWR and BS results was only 7% when the reactant frequencies were used. Hence, it is unlikely that the fitting error is the main source for the 60% error in the rate constant. The main error in the present IWR method may arise from the fact that the vibrational frequencies at the TS are different from the reactant frequencies that are used to obtain the w function. To check such a possibility, we carried out RRKM calculations for M10 with the same E0 but increasing ∆Sq to 10 eu, which is a typical value for a loose transition state5 reaction. Here again, the rateenergy data calculated by IWR were much better than those by WR, even though the deviation from the BS results was larger than in the E0 ) 0.5 eV and ∆Sq ) 0 eu case, as expected. The rate constant in the 0.1 s-1 range differed by a factor of 6. The RRKM calculations were done with an E0 of 1.0 eV and a ∆Sq of 10 eu also. Here, the IWR and BS results were in excellent agreement as in the E0 ) 0.5 eV and ∆Sq ) 0 eu case. The RRKM calculations were done for peptides consisting of various amino acids also. These included well-known peptides such as angiotensin I (DRVYIHPFHL, monoisotopic relative molecular mass (RMM) of 1295.7) and 100 randomly generated peptides consisting of ten amino acid residues. We also carried out calculations for various fictitious proteins such as the fictitious 8-mer of angiotensin I, (DRVYIHPFHL)8, with a monoisotopic RMM of 10 239.4 to check the reliability of the

Sun et al. present IWR method for higher mass proteins. The general trend in all these cases was the same as in the M10 case: overestimation of k near 0.1 s-1 by 60-80% in the calculations with E0 ) 0.5 eV and ∆Sq ) 0 eu and overestimation by a factor of 6 with E0 ) 0.5 eV and ∆Sq ) 10 eu. From the results presented so far, it is obvious that a rateenergy relation calculated by the IWR method reproduces the corresponding BS result satisfactorily except when E0 is small and ∆Sq is large at the same time. In the present work, the vibrational frequency set at the TS is estimated by adjusting some of the frequencies of the reactant such that the postulated ∆Sq results. As ∆Sq gets larger, these adjusted frequencies get smaller. Then, the state sum evaluated using the w function derived with the reactant frequency data deviates more from the correct value, resulting in larger deviation in the rate constant. When E0 gets larger also, the agreement between the IWR and BS results gets better even when ∆Sq is large. The explanation for the better agreement at larger E0 is as follows. As E0 increases, the rate constant at a given internal energy decreases rapidly. In fact, the internal energy needed to maintain the rate constant at the same value, and hence the internal energy at the TS also, increases almost in proportion to E0. At high internal energy, however, the influence of the above lowfrequency vibrations at the TS becomes less important, resulting in better agreement between the IWR and BS rate constants. Even though the present IWR method is not adequate to reproduce the BS rate-energy relation for a simultaneously small E0 and large ∆Sq case such as E0 ) 0.5 eV and ∆Sq ) 10 eu, it is to be mentioned that such a case is unlikely to be encountered in protein dissociations. In dissociation reactions, a large value of ∆Sq, or the occurrence of a loose transition state,5 is usually associated with simple bond cleavage reactions, which tend to have a large E0 value. It is well-known in the field of mass spectrometry that the b and y type fragment ions are generated preferentially when the internal energy of a protonated peptide is not high,26 which indicates that they are generated via reaction paths with small E0 values. According to the DFT calculation for the dissociation of [G3 + H]+ carried out by Paizs and Suhai,22 generation of the b2 ion occurred with the smallest value of E0 (0.42 eV) and dominated in the low internal energy range. The value of ∆Sq evaluated using the frequencies at the reactant and TS geometries supplied by Paizs and Suhai was -2.65 eu. This is in agreement with our speculation that there is probably no dissociation channel with simultaneously small E0 and large ∆Sq values for protein ions. If such a channel existed, it would have dominated the fragment ion spectra over the entire internal energy range. However, it is known26 that the major fragment ion types in the dissociation of peptide and small protein ions change from b and y to a, d, v, w, and x as the internal energy increases. Absence of reaction channels with simultaneously small E0 and large ∆Sq values means that the IWR method developed in this work is probably reliable for dissociation of protein ions. Without attached protons, the critical energy for the dissociation of a neutral protein will be probably larger than the corresponding value for the protonated form. The forgoing discussion on the influence of entropy on the accuracy of the IWR method has arisen because the w function derived with the reactant frequencies in this work is not quite adequate at the TS. A related problem may arise from the fact that the reactant frequencies used in this work are those estimated for linear peptides and proteins. The frequencies of a protein may be affected by hydrogen bonding even in the gas phase. Then, the w function derived in this work may be invalid

Improved WR Approximation for Proteins to deal with the dissociation of gas-phase proteins, rendering the present method useless. Out of this concern, we attempted some primitive calculations for peptides with intramolecular hydrogen bonding. For this purpose, we assumed that the frequencies affected by hydrogen bonding are those of the N-H and CdO stretching modes. Then, the frequencies of these modes in the set stored for each amino acid residue was reduced by 5% based on the spectral correlation appearing in the literature.27 The rate-energy relations thus obtained were hardly distinguishable from the original data, suggesting that the w function derived by the present method can be used even when intramolecular hydrogen bonding is present in a protein. Finally, we compared the rate-energy relations calculated with E0 ) 0.5 eV and ∆Sq ) 0 eu for the monomer, 8-mer, and 80-mer of angiotensin I. The internal energies corresponding to, for example, 103 s-1 in these molecules were 1.97, 14.21, and 140.01 eV, respectively, increasing nearly in proportion to the molecular mass. This is in agreement with our previous suggestion28 that the internal energy needed to observe a particular type of protein reaction with the same rate constant increases almost in proportion to the number of degrees of freedom, which, in turn, is almost proportional to the molecular mass of proteins. Because the zero-point energies of proteins increase almost in proportion to the molecular mass also, 42.18, 332.77, and 3321.73 eV for the monomer, 8-mer, and 80-mer, respectively, the three rate-energy curves can be brought into near coincidence by drawing them with the scaled energy in the abscissa. IV. Conclusion Even though the BS algorithm is efficient and accurate in evaluating the vibrational state sum and density needed in the RRKM calculation of a unimolecular reaction, its application to biopolymers is limited because the computational time increases rapidly with the molecular mass. In this work, the WR approximation used in the semi-classical calculation of a rate constant has been improved such that the rate constant for a unimolecular reaction of a protein evaluated by this method closely reproduces the BS result. Its main advantage lies in the fact that a rate constant can be calculated instantly regardless of the protein mass. It has been found that the rate constant calculated by this method differs from the BS result significantly for reactions occurring with simultaneously small E0 and large ∆Sq values. Certainly, it is a weakness of the present method even though such a situation is unlikely to be encountered in actual protein dissociations. Another weakness of the present approach is that the method is valid only for peptides and proteins. Completely new functions must be derived for other

J. Phys. Chem. B, Vol. 111, No. 10, 2007 2751 biopolymers such as nucleic acids and carbohydrates, even though the method to derive such functions would be the same as in this work. In this regard, it may be worthwhile to investigate other approximate methods developed previously such that an efficient and accurate method with general applicability to any biopolymer can be established. Acknowledgment. Meiling Sun thanks the Ministry of Education for the Brain Korea 21 fellowship. The software developed in this work will be made freely available. References and Notes (1) Holbrook, K. A.; Pilling, M. J.; Robertson, S. H. Unimolecular Reactions, 2nd ed.; Wiley: Chichester, U.K., 1996. (2) Marcus, R. A.; Rice, O. K. J. Phys. Colloid Chem. 1951, 55, 894. (3) Rosenstock, H. M.; Wallenstein, M.B.; Wahrhaftig, A. L.; Eyring, H. Proc. Nat. Acad. Sci. U.S.A. 1952, 38, 667. (4) Steinfeld, J. I.; Francisco, J. S.; Hase, W. L. Chemical Kinetics and Dynamics; Prentice Hall: Englewood Cliffs, NJ, 1989; pp 342-401. (5) Gilbert, R.G.; Smith, S. C. Theory of Unimolecular and Recombination Reactions; Blackwell Scientific: Oxford, U.K., 1990; pp 136211. (6) Baer, T.; Hase, W. L. Unimolecular Reaction Dynamics: Theory and Experiments; Oxford University Press: New York, 1996; pp 171211. (7) Lifshitz, C. AdV. Mass Spectrom. 1989, 11A, 713. (8) Baer, T.; Mayer, P. M. J. Am. Soc. Mass Spectrom. 1997, 8, 103. (9) Laskin, J.; Bailey, T. H.; Futrell, J. H. Int. J. Mass Spectrom. 2006, 249-250, 462. (10) Rosenstock, H. M.; Stockbauer, R.; Parr, A. C. J. Chem. Phys. 1979, 71, 3708. (11) Rosenstock, H. M.; Stockbauer, R.; Parr, A. C. J. Chem. Phys. 1980, 73, 773. (12) Lifshitz, C. Mass Spectrom. ReV. 1982, 1, 309. (13) Moon, J. H.; Oh. J. Y.; Kim, M. S. J. Am. Soc. Mass Spectrom. 2006, in press. (14) Biemann, K.; Martin, S. A. Mass Spectrom. ReV. 1987, 6, 1. (15) Paizs, B.; Suhai, S. Mass Spectrom. ReV. 2005, 24, 508. (16) McCloskey, J. A. Mass Spectrometry, Methods in Enzymology; Academic Press: San Diego, 1990; Vol. 193, pp 351-360. (17) Whitten, G. Z.; Rabinovitch, B. S. J. Chem. Phys. 1963, 38, 2466. (18) Morse, P. M.; Feshbach, H. Methods of Theoretical Physics. Part I; McGraw-Hill: New York, 1953; pp 434-443. (19) Derrick, P. J.; Lloyd, P. M.; Christie, J. R. Physical Chemistry of Ion Reactions in AdV. Mass Spectrometry; Wiley: Chichester, U.K. 1995; Vol. 13, pp 25-52. (20) Beyer, T.; Swinehart, D. F. Commun. ACM 1973, 16, 379. (21) Rabinovitch, B. S.; Diesen, R. W. J. Chem. Phys. 1959, 30, 735. (22) Paizs, B.; Suhai, S. Rapid Commun. Mass Spectrom. 2002, 16, 375. (23) Polce, M. J.; Ren, D.; Wesdemiotis, C. J. Mass Spectrom. 2000, 35, 1351. (24) Klassen, J. S.; Kebarle, P. J. Am. Chem. Soc. 1997, 119, 6552. (25) Allen, G. Protein; Jai Press: London, 1997; Vol. 1, p 9. (26) Johnson, R. S.; Martin, S. A.; Biemann, K. Int. J. Mass Spectrom. Ion Processes 1988, 86, 137. (27) Dollish, F. R.; Fateley, W. G.; Bentley, F. F. Characteristic Raman Frequencies of Organic Compounds; Wiley: London, 1974; Chapter 9. (28) Oh, J. Y.; Moon, J. H.; Kim, M. S. J. Am. Soc. Mass Spectrom. 2004, 15, 1248.