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Stacking (chemistry)

April 11, 2024

In chemistry, pi stacking (also called π–π stacking) refers to the presumptive attractive, noncovalent pi interactions (orbital overlap) between the pi bonds of aromatic rings. However this is a misleading description of the phenomena since direct stacking of aromatic rings (the "sandwich interaction") is electrostatically repulsive. What is more commonly observed (see figure to the right) is either a staggered stacking (parallel displaced) or pi-teeing (perpendicular T-shaped) interaction both of which are electrostatic attractive[1][2] For example, the most commonly observed interactions between aromatic rings of amino acid residues in proteins is a staggered stacked followed by a perpendicular orientation. Sandwiched orientations are relatively rare.[3]

Three representative conformations of the benzene dimer

Pi stacking is repulsive as it places carbon atoms with partial negative charges from one ring on top of other partial negatively charged carbon atoms from the second ring and hydrogen atoms with partial positive charges on top of other hydrogen atoms that likewise carry partial positive charges.[1] In staggered stacking, one of the two aromatic rings is offset sideways so that the carbon atoms with partial negative charge in the first ring are placed above hydrogen atoms with partial positive charge in the second ring so that the electrostatic interactions become attractive. Likewise, pi-teeing interactions in which the two rings are oriented perpendicular to either other is electrostatically attractive as it places partial positively charged hydrogen atoms in close proximity to partially negatively charged carbon atoms. An alternative explanation for the preference for staggered stacking is due to the balance between van der Waals interactions (attractive dispersion plus Pauli repulsion).[4]

These staggered stacking and π-teeing interactions between aromatic rings are important in nucleobase stacking within DNA and RNA molecules, protein folding, template-directed synthesis, materials science, and molecular recognition. Despite the wide use of term pi stacking in the scientific literature, there is no theoretical justification for its use.[1]

Evidence against pi stacking edit

The benzene dimer is the prototypical system for the study of pi stacking, and is experimentally bound by 8–12 kJ/mol (2–3 kcal/mol) in the gas phase with a separation of 4.96 Å between the centers of mass for the T-shaped dimer. The small binding energy makes the benzene dimer difficult to study experimentally, and the dimer itself is only stable at low temperatures and is prone to cluster.[5]

Other evidence against pi stacking comes from X-ray crystal structure determination. Perpendicular and offset parallel configurations can be observed in the crystal structures of many simple aromatic compounds.[5] Similar offset parallel or perpendicular geometries were observed in a survey of high-resolution x-ray protein crystal structures in the Protein Data Bank.[6] Analysis of the aromatic amino acids phenylalanine, tyrosine, histidine, and tryptophan indicates that dimers of these side chains have many possible stabilizing interactions at distances larger than the average van der Waals radii.[3]

Geometric configurations edit

The preferred geometries of the benzene dimer have been modeled at a high level of theory with MP2-R12/A computations and very large counterpoise-corrected aug-cc-PVTZ basis sets.[5] The two most stable conformations are the parallel displaced and T-shaped, which are essentially isoenergetic. In contrast, the sandwich configuration maximizes overlap of the pi system, which destabilizes the interaction. The sandwich configuration represents an energetic saddle point, which is consistent with the relative rarity of this configuration in x-ray crystal data.[citation needed]

 
Quadrupole moments of benzene and hexafluorobenzene. The polarity is inverted due to differences in electronegativity for hydrogen and fluorine relative to carbon.

The relative binding energies of these three geometric configurations of the benzene dimer can be explained by a balance of quadrupole/quadrupole and London dispersion forces. While benzene does not have a dipole moment, it has a strong quadrupole moment.[7] The local C–H dipole means that there is positive charge on the atoms in the ring and a correspondingly negative charge representing an electron cloud above and below the ring. The quadrupole moment is reversed for hexafluorobenzene due to the electronegativity of fluorine. The benzene dimer in the sandwich configuration is stabilized by London dispersion forces but destabilized by repulsive quadrupole/quadrupole interactions. By offsetting one of the benzene rings, the parallel displaced configuration reduces these repulsive interactions and is stabilized. The large polarizability of aromatic rings lead to dispersive interactions as major contribution to stacking effects. These play a major role for interactions of nucleobases e.g. in DNA.[8] The T-shaped configuration enjoys favorable quadrupole/quadrupole interactions, as the positive quadrupole of one benzene ring interacts with the negative quadrupole of the other. The benzene rings are furthest apart in this configuration, so the favorable quadrupole/quadrupole interactions evidently compensate for diminished dispersion forces.

Substituent effects edit

The ability to fine-tune pi stacking interactions would be useful in numerous synthetic efforts. One example would be to increase the binding affinity of a small-molecule inhibitor to an enzyme pocket containing aromatic residues. The effects of heteroatoms[6] and substituents on pi stacking interactions is difficult to model and a matter of debate.

Electrostatic model edit

An early model for the role of substituents in pi stacking interactions was proposed by Hunter and Sanders.[9] They used a simple mathematical model based on sigma and pi atomic charges, relative orientations, and van der Waals interactions to qualitatively determine that electrostatics are dominant in substituent effects. According to their model, electron-withdrawing groups reduce the negative quadrupole of the aromatic ring and thereby favor parallel displaced and sandwich conformations. Contrastingly, electron donating groups increase the negative quadrupole, which may increase the interaction strength in a T-shaped configuration with the proper geometry. Based on this model, the authors proposed a set of rules governing pi stacking interactions which prevailed until more sophisticated computations were applied.[citation needed]

Experimental evidence for the Hunter–Sanders model was provided by Siegel et al. using a series of substituted syn- and anti-1,8-di-o-tolylnaphthalenes.[10] In these compounds the aryl groups "face-off" in a stacked geometry due to steric crowding, and the barrier to epimerization was measured by nuclear magnetic resonance spectroscopy. The authors reported that aryl rings with electron-withdrawing substituents had higher barriers to rotation. The interpretation of this result was that these groups reduced the electron density of the aromatic rings, allowing more favorable sandwich pi stacking interactions and thus a higher barrier. In other words, the electron-withdrawing groups resulted in "less unfavorable" electrostatic interactions in the ground state.[citation needed]

 
Double mutant cycle used by Hunter et al.[11] to probe T-shaped π-stacking interactions

Hunter et al. applied a more sophisticated chemical double mutant cycle with a hydrogen-bonded "zipper" to the issue of substituent effects in pi stacking interactions.[11] This technique has been used to study a multitude of noncovalent interactions. The single mutation, in this case changing a substituent on an aromatic ring, results in secondary effects such as a change in hydrogen bond strength. The double mutation quantifies these secondary interactions, such that even a weak interaction of interest can be dissected from the array. Their results indicate that more electron-withdrawing substituents have less repulsive pi stacking interactions. Correspondingly, this trend was exactly inverted for interactions with pentafluorophenylbenzene, which has a quadrupole moment equal in magnitude but opposite in sign as that of benzene.[7] The findings provide direct evidence for the Hunter–Sanders model. However, the stacking interactions measured using the double mutant method were surprisingly small, and the authors note that the values may not be transferable to other systems.

In a follow-up study, Hunter et al. verified to a first approximation that the interaction energies of the interacting aromatic rings in a double mutant cycle are dominated by electrostatic effects.[12] However, the authors note that direct interactions with the ring substituents, discussed below, also make important contributions. Indeed, the interplay of these two factors may result in the complicated substituent- and geometry-dependent behavior of pi stacking interactions.

Direct interaction model edit

The Hunter–Sanders model has been criticized by numerous research groups offering contradictory experimental and computational evidence of pi stacking interactions that are not governed primarily by electrostatic effects.[13]

The clearest experimental evidence against electrostatic substituent effects was reported by Rashkin and Waters.[14] They used meta- and para-substituted N-benzyl-2-(2-fluorophenyl)-pyridinium bromides, which stack in a parallel displaced conformation, as a model system for pi stacking interactions. In their system, a methylene linker prohibits favorable T-shaped interactions. As in previous models, the relative strength of pi stacking interactions was measured by NMR as the rate of rotation about the biaryl bond, as pi stacking interactions are disrupted in the transition state. Para-substituted rings had small rotational barriers which increased with increasingly electron-withdrawing groups, consistent with prior findings. However, meta-substituted rings had much larger barriers of rotation despite having nearly identical electron densities in the aromatic ring. The authors explain this discrepancy as direct interaction of the edge of hydrogen atoms of one ring with the electronegative substituents on the other ring. This claim is supported by chemical shift data of the proton in question.[citation needed]

Much of the detailed analyses of the relative contributions of factors in pi stacking have been borne out by computation. Sherill and Sinnokrot reported a surprising finding using high-level theory that all substituted benzene dimers have more favorable binding interactions than a benzene dimer in the sandwich configuration.[15] Later computational work from the Sherill group revealed that the substituent effects for the sandwich configuration are additive, which points to a strong influence of dispersion forces and direct interactions between substituents.[16] It was noted that interactions between substituted benzenes in the T-shaped configuration were more complex. Finally, Sherill and Sinnokrot argue in their review article that any semblance of a trend based on electron donating or withdrawing substituents can be explained by exchange-repulsion and dispersion terms.[17]

 
Houk and Wheeler's [18] computational model of substituent direct interactions in pi stacking.

Houk and Wheeler also provide compelling computational evidence for the importance of direct interaction in pi stacking.[18] In their analysis of substituted benzene dimers in a sandwich conformation, they were able to recapitulate their findings using an exceedingly simple model where the substituted benzene, Ph–X, was replaced by H–X. Remarkably, this crude model resulted in the same trend in relative interaction energies, and correlated strongly with the values calculated for Ph–X. This finding suggests that substituent effects in the benzene dimer are due to direct interaction of the substituent with the aromatic ring, and that the pi system of the substituted benzene is not involved. This latter point is expanded upon below.

In summary, it would seem that the relative contributions of electrostatics, dispersion, and direct interactions to the substituent effects seen in pi stacking interactions are highly dependent on geometry and experimental design. The lack of consensus on the matter may simply reflect the complexity of the issue.

Requirement of aromaticity edit

The conventional understanding of pi stacking involves quadrupole interactions between delocalized electrons in p-orbitals. In other words, aromaticity should be required for this interaction to occur. However, several groups have provided contrary evidence, calling into question whether pi stacking is a unique phenomenon or whether it extends to other neutral, closed-shell molecules.

In an experiment not dissimilar from others mentioned above, Paliwal and coauthors constructed a molecular torsion balance from an aryl ester with two conformational states.[19] The folded state had a well-defined pi stacking interaction with a T-shaped geometry, whereas the unfolded state had no aryl–aryl interactions. The NMR chemical shifts of the two conformations were distinct and could be used to determine the ratio of the two states, which was interpreted as a measure of intramolecular forces. The authors report that a preference for the folded state is not unique to aryl esters. For example, the cyclohexyl ester favored the folded state more so than the phenyl ester, and the tert-butyl ester favored the folded state by a preference greater than that shown by any aryl ester. This suggests that aromaticity is not a strict requirement for favorable interaction with an aromatic ring.

Other evidence for non-aromatic pi stacking interactions results include critical studies in theoretical chemistry, explaining the underlying mechanisms of empirical observations. Grimme reported that the interaction energies of smaller dimers consisting of one or two rings are very similar for both aromatic and saturated compounds.[20] This finding is of particular relevance to biology, and suggests that the contribution of pi systems to phenomena such as stacked nucleobases may be overestimated. However, it was shown that an increased stabilizing interaction is seen for large aromatic dimers. As previously noted, this interaction energy is highly dependent on geometry. Indeed, large aromatic dimers are only stabilized relative to their saturated counterparts in a sandwich geometry, while their energies are similar in a T-shaped interaction.

 
a) Substituted naphthalenes and b) Homodesmotic dissection of benzene used by Bloom and Wheeler[21] to quantify the effects of delocalization on pi stacking.

A more direct approach to modeling the role of aromaticity was taken by Bloom and Wheeler.[21] The authors compared the interactions between benzene and either 2-methylnaphthalene or its non-aromatic isomer, 2-methylene-2,3-dihydronaphthalene. The latter compound provides a means of conserving the number of p-electrons while, however, removing the effects of delocalization. Surprisingly, the interaction energies with benzene are higher for the non-aromatic compound, suggesting that pi-bond localization is favorable in pi stacking interactions. The authors also considered a homodesmotic dissection of benzene into ethylene and 1,3-butadiene and compared these interactions in a sandwich with benzene. Their calculation indicates that the interaction energy between benzene and homodesmotic benzene is higher than that of a benzene dimer in both sandwich and parallel displaced conformations, again highlighting the favorability of localized pi-bond interactions. These results strongly suggest that aromaticity is not required for pi stacking interactions in this model.

Even in light of this evidence, Grimme concludes that pi stacking does indeed exist.[20] However, he cautions that smaller rings, particularly those in T-shaped conformations, do not behave significantly differently from their saturated counterparts, and that the term should be specified for larger rings in stacked conformations which do seem to exhibit a cooperative pi electron effect.

Applications edit

 
A fullerene bound in a buckycatcher through aromatic stacking interactions.[22]

A powerful demonstration of stacking is found in the buckycatcher.[22] This molecular tweezer is based on two concave buckybowls with a perfect fit for one convex fullerene molecule. Complexation takes place simply by evaporating a toluene solution containing both compounds. In solution an association constant of 8600 M−1 is measured based on changes in NMR chemical shifts.[citation needed]

 
Tacrine bound to acetylcholinesterase (PDB 1ACJ). A pi stacking interaction between tacrine (blue) and Trp84 (red) is proposed.

Pi stacking is prevalent in protein crystal structures, and also contributes to the interactions between small molecules and proteins. As a result, pi–pi and cation–pi interactions are important factors in rational drug design.[23] One example is the FDA-approved acetylcholinesterase (AChE) inhibitor tacrine which is used in the treatment of Alzheimer's disease. Tacrine is proposed to have a pi stacking interaction with the indolic ring of Trp84, and this interaction has been exploited in the rational design of novel AChE inhibitors.[24]

Addition in pharmacological active compounds edit

 
Cocaine analog 21b, an antagonist

Several variants of pi coordinated phenyls have even been tested using transition metals for stacking η6-phenyltropanes, using cyclopentadienyl and tricarbonyl in place of a benzene. Which in the case of the tricarbonyl doubled the compound's affinity for its intended ligand site (posited as due to resultant electrostatic influences being more conducive to the target).[25]

In supramolecular assembly edit

 
Figure 2. The Stoddart synthesis of [2] catenane...

π systems are important building blocks in supramolecular assembly because of their versatile noncovalent interactions with various functional groups. A notable example of applying π–π interactions in supramolecular assembly is the synthesis of catenane. The major challenge for the synthesis of catenane is to interlock molecules in a controlled fashion. Stoddart and co-workers developed a series of systems utilizing the strong π–π interactions between electron-rich benzene derivatives and electron-poor pyridinium rings.[26] [2]Catanene was synthesized by reacting bis(pyridinium) (A), bisparaphenylene-34-crown-10 (B), and 1, 4-bis(bromomethyl)benzene (C) (Fig. 2). The π–π interaction between A and B directed the formation of an interlocked template intermediate that was further cyclized by substitution reaction with compound C to generate the [2]catenane product.

See also edit

References edit

  1. ^ a b c Martinez CR, Iverson BL (2012). "Rethinking the term "pi-stacking"". Chemical Science. 3 (7): 2191. doi:10.1039/c2sc20045g. hdl:2152/41033. ISSN 2041-6520. S2CID 95789541.
  2. ^ Lewis M, Bagwill C, Hardebeck L, Wireduaah S (2016). "Modern Computational Approaches to Understanding Interactions of Aromatics". In Johnson DW, Hof F (eds.). Aromatic Interactions: Frontiers in Knowledge and Application. England: Royal Society of Chemistry. pp. 1–17. ISBN 978-1-78262-662-6.
  3. ^ a b McGaughey GB, Gagné M, Rappé AK (June 1998). "pi-Stacking interactions. Alive and well in proteins". The Journal of Biological Chemistry. 273 (25): 15458–63. doi:10.1074/jbc.273.25.15458. PMID 9624131.
  4. ^ Carter-Fenk K, Herbert JM (November 2020). "Reinterpreting π-stacking". Physical Chemistry Chemical Physics. 22 (43): 24870–24886. doi:10.1039/d0cp05039c. PMID 33107520. S2CID 225083299.
  5. ^ a b c Sinnokrot MO, Valeev EF, Sherrill CD (September 2002). "Estimates of the ab initio limit for pi-pi interactions: the benzene dimer". Journal of the American Chemical Society. 124 (36): 10887–10893. doi:10.1021/ja025896h. PMID 12207544.
  6. ^ a b Huber RG, Margreiter MA, Fuchs JE, von Grafenstein S, Tautermann CS, Liedl KR, Fox T (May 2014). "Heteroaromatic π-stacking energy landscapes". Journal of Chemical Information and Modeling. 54 (5): 1371–1379. doi:10.1021/ci500183u. PMC 4037317. PMID 24773380.
  7. ^ a b Battaglia MR, Buckingham AD, Williams JH (1981). "The electric quadrupole moments of benzene and hexafluorobenzene". Chem. Phys. Lett. 78 (3): 421–423. Bibcode:1981CPL....78..421B. doi:10.1016/0009-2614(81)85228-1.
  8. ^ Riley KE, Hobza P (April 2013). "On the importance and origin of aromatic interactions in chemistry and biodisciplines". Accounts of Chemical Research. 46 (4): 927–936. doi:10.1021/ar300083h. PMID 22872015.
  9. ^ Hunter CA, Sanders JK (1990). "The nature of π–π Interactions". J. Am. Chem. Soc. 112 (14): 5525–5534. doi:10.1021/ja00170a016.
  10. ^ Cozzi F, Cinquini M, Annuziata R, Siegel JS (1993). "Dominance of polar/.pi. Over charge-transfer effects in stacked phenyl interactions". J. Am. Chem. Soc. 115 (12): 5330–5331. doi:10.1021/ja00065a069.
  11. ^ a b Cockroft SL, Hunter CA, Lawson KR, Perkins J, Urch CJ (June 2005). "Electrostatic control of aromatic stacking interactions". Journal of the American Chemical Society. 127 (24): 8594–8595. doi:10.1021/ja050880n. PMID 15954755.
  12. ^ Cockroft SL, Perkins J, Zonta C, Adams H, Spey SE, Low CM, et al. (April 2007). "Substituent effects on aromatic stacking interactions". Organic & Biomolecular Chemistry. 5 (7): 1062–1080. doi:10.1039/b617576g. PMID 17377660. S2CID 37409177.
  13. ^ Martinez, Chelsea R.; Iverson, Brent L. (2012). "Rethinking the term "pi-stacking"". Chemical Science. 3 (7): 2191. doi:10.1039/C2SC20045G. hdl:2152/41033.
  14. ^ Rashkin MJ, Waters ML (March 2002). "Unexpected substituent effects in offset pi-pi stacked interactions in water". Journal of the American Chemical Society. 124 (9): 1860–1861. doi:10.1021/ja016508z. PMID 11866592.
  15. ^ Sinnokrot MO, Sherrill CD (2003). "Unexpected Substituent Effects in Face-to-Face π-Stacking Interactions". J. Phys. Chem. A. 107 (41): 8377–8379. Bibcode:2003JPCA..107.8377S. doi:10.1021/jp030880e.
  16. ^ Ringer AL, Sinnokrot MO, Lively RP, Sherrill CD (May 2006). "The effect of multiple substituents on sandwich and T-shaped pi-pi interactions". Chemistry: A European Journal. 12 (14): 3821–3828. doi:10.1002/chem.200501316. PMID 16514687.
  17. ^ Sinnokrot MO, Sherrill CD (September 2006). "High-accuracy quantum mechanical studies of pi-pi interactions in benzene dimers". The Journal of Physical Chemistry A. 110 (37): 10656–10668. Bibcode:2006JPCA..11010656S. doi:10.1021/jp0610416. PMID 16970354.
  18. ^ a b Wheeler SE, Houk KN (August 2008). "Substituent effects in the benzene dimer are due to direct interactions of the substituents with the unsubstituted benzene". Journal of the American Chemical Society. 130 (33): 10854–10855. doi:10.1021/ja802849j. PMC 2655233. PMID 18652453.
  19. ^ Paliwal S, Geib S, Wilcox CS (1994). "Molecular Torsion Balance for Weak Molecular Recognition Forces. Effects of "Tilted-T" Edge-to-Face Aromatic Interactions on Conformational Selection and Solid-State Structure". J. Am. Chem. Soc. 116 (10): 4497–4498. doi:10.1021/ja00089a057.
  20. ^ a b Grimme S (2008). "Do special noncovalent pi-pi stacking interactions really exist?". Angewandte Chemie. 47 (18): 3430–3434. doi:10.1002/anie.200705157. PMID 18350534.
  21. ^ a b Bloom JW, Wheeler SE (2011). "Taking the Aromaticity out of Aromatic Interactions". Angew. Chem. 123 (34): 7993–7995. Bibcode:2011AngCh.123.7993B. doi:10.1002/ange.201102982.
  22. ^ a b Sygula A, Fronczek FR, Sygula R, Rabideau PW, Olmstead MM (April 2007). "A double concave hydrocarbon buckycatcher". Journal of the American Chemical Society. 129 (13): 3842–3843. doi:10.1021/ja070616p. PMID 17348661. S2CID 25154754.
  23. ^ Babine RE, Bender SL (August 1997). "Molecular Recognition of Proteinminus signLigand Complexes: Applications to Drug Design". Chemical Reviews. 97 (5): 1359–1472. doi:10.1021/cr960370z. PMID 11851455.
  24. ^ da Silva CH, Campo VL, Carvalho I, Taft CA (October 2006). "Molecular modeling, docking and ADMET studies applied to the design of a novel hybrid for treatment of Alzheimer's disease". Journal of Molecular Graphics & Modelling. 25 (2): 169–175. doi:10.1016/j.jmgm.2005.12.002. PMID 16413803.
  25. ^ Singh S (March 2000). "Chemistry, design, and structure-activity relationship of cocaine antagonists". Chemical Reviews. 100 (3): 925–1024. doi:10.1021/cr9700538. PMID 11749256.
  26. ^ Ashton PR, Goodnow TT, Kaifer AE, Reddington MV, Slawin AM, Spencer N, et al. (1989). "A [2] Catenane Made to Order". J. Angew. Chem. Int. Ed. 28 (10): 1396–1399. doi:10.1002/anie.198913961.

External links edit

  • Luo R, Gilson HS, Potter MJ, Gilson MK (January 2001). "The physical basis of nucleic acid base stacking in water". Biophysical Journal. 80 (1): 140–148. Bibcode:2001BpJ....80..140L. doi:10.1016/S0006-3495(01)76001-8. PMC 1301220. PMID 11159389.
  • Larry Wolf (2011): π-π (π-Stacking) interactions: origin and modulation

April 11, 2024
stacking, chemistry, chemistry, stacking, also, called, stacking, refers, presumptive, attractive, noncovalent, interactions, orbital, overlap, between, bonds, aromatic, rings, however, this, misleading, description, phenomena, since, direct, stacking, aromati. In chemistry pi stacking also called p p stacking refers to the presumptive attractive noncovalent pi interactions orbital overlap between the pi bonds of aromatic rings However this is a misleading description of the phenomena since direct stacking of aromatic rings the sandwich interaction is electrostatically repulsive What is more commonly observed see figure to the right is either a staggered stacking parallel displaced or pi teeing perpendicular T shaped interaction both of which are electrostatic attractive 1 2 For example the most commonly observed interactions between aromatic rings of amino acid residues in proteins is a staggered stacked followed by a perpendicular orientation Sandwiched orientations are relatively rare 3 Three representative conformations of the benzene dimerPi stacking is repulsive as it places carbon atoms with partial negative charges from one ring on top of other partial negatively charged carbon atoms from the second ring and hydrogen atoms with partial positive charges on top of other hydrogen atoms that likewise carry partial positive charges 1 In staggered stacking one of the two aromatic rings is offset sideways so that the carbon atoms with partial negative charge in the first ring are placed above hydrogen atoms with partial positive charge in the second ring so that the electrostatic interactions become attractive Likewise pi teeing interactions in which the two rings are oriented perpendicular to either other is electrostatically attractive as it places partial positively charged hydrogen atoms in close proximity to partially negatively charged carbon atoms An alternative explanation for the preference for staggered stacking is due to the balance between van der Waals interactions attractive dispersion plus Pauli repulsion 4 These staggered stacking and p teeing interactions between aromatic rings are important in nucleobase stacking within DNA and RNA molecules protein folding template directed synthesis materials science and molecular recognition Despite the wide use of term pi stacking in the scientific literature there is no theoretical justification for its use 1 Contents 1 Evidence against pi stacking 2 Geometric configurations 3 Substituent effects 3 1 Electrostatic model 3 2 Direct interaction model 4 Requirement of aromaticity 5 Applications 5 1 Addition in pharmacological active compounds 6 In supramolecular assembly 7 See also 8 References 9 External linksEvidence against pi stacking editThe benzene dimer is the prototypical system for the study of pi stacking and is experimentally bound by 8 12 kJ mol 2 3 kcal mol in the gas phase with a separation of 4 96 A between the centers of mass for the T shaped dimer The small binding energy makes the benzene dimer difficult to study experimentally and the dimer itself is only stable at low temperatures and is prone to cluster 5 Other evidence against pi stacking comes from X ray crystal structure determination Perpendicular and offset parallel configurations can be observed in the crystal structures of many simple aromatic compounds 5 Similar offset parallel or perpendicular geometries were observed in a survey of high resolution x ray protein crystal structures in the Protein Data Bank 6 Analysis of the aromatic amino acids phenylalanine tyrosine histidine and tryptophan indicates that dimers of these side chains have many possible stabilizing interactions at distances larger than the average van der Waals radii 3 Geometric configurations editThe preferred geometries of the benzene dimer have been modeled at a high level of theory with MP2 R12 A computations and very large counterpoise corrected aug cc PVTZ basis sets 5 The two most stable conformations are the parallel displaced and T shaped which are essentially isoenergetic In contrast the sandwich configuration maximizes overlap of the pi system which destabilizes the interaction The sandwich configuration represents an energetic saddle point which is consistent with the relative rarity of this configuration in x ray crystal data citation needed nbsp Quadrupole moments of benzene and hexafluorobenzene The polarity is inverted due to differences in electronegativity for hydrogen and fluorine relative to carbon The relative binding energies of these three geometric configurations of the benzene dimer can be explained by a balance of quadrupole quadrupole and London dispersion forces While benzene does not have a dipole moment it has a strong quadrupole moment 7 The local C H dipole means that there is positive charge on the atoms in the ring and a correspondingly negative charge representing an electron cloud above and below the ring The quadrupole moment is reversed for hexafluorobenzene due to the electronegativity of fluorine The benzene dimer in the sandwich configuration is stabilized by London dispersion forces but destabilized by repulsive quadrupole quadrupole interactions By offsetting one of the benzene rings the parallel displaced configuration reduces these repulsive interactions and is stabilized The large polarizability of aromatic rings lead to dispersive interactions as major contribution to stacking effects These play a major role for interactions of nucleobases e g in DNA 8 The T shaped configuration enjoys favorable quadrupole quadrupole interactions as the positive quadrupole of one benzene ring interacts with the negative quadrupole of the other The benzene rings are furthest apart in this configuration so the favorable quadrupole quadrupole interactions evidently compensate for diminished dispersion forces Substituent effects editThe ability to fine tune pi stacking interactions would be useful in numerous synthetic efforts One example would be to increase the binding affinity of a small molecule inhibitor to an enzyme pocket containing aromatic residues The effects of heteroatoms 6 and substituents on pi stacking interactions is difficult to model and a matter of debate Electrostatic model edit An early model for the role of substituents in pi stacking interactions was proposed by Hunter and Sanders 9 They used a simple mathematical model based on sigma and pi atomic charges relative orientations and van der Waals interactions to qualitatively determine that electrostatics are dominant in substituent effects According to their model electron withdrawing groups reduce the negative quadrupole of the aromatic ring and thereby favor parallel displaced and sandwich conformations Contrastingly electron donating groups increase the negative quadrupole which may increase the interaction strength in a T shaped configuration with the proper geometry Based on this model the authors proposed a set of rules governing pi stacking interactions which prevailed until more sophisticated computations were applied citation needed Experimental evidence for the Hunter Sanders model was provided by Siegel et al using a series of substituted syn and anti 1 8 di o tolylnaphthalenes 10 In these compounds the aryl groups face off in a stacked geometry due to steric crowding and the barrier to epimerization was measured by nuclear magnetic resonance spectroscopy The authors reported that aryl rings with electron withdrawing substituents had higher barriers to rotation The interpretation of this result was that these groups reduced the electron density of the aromatic rings allowing more favorable sandwich pi stacking interactions and thus a higher barrier In other words the electron withdrawing groups resulted in less unfavorable electrostatic interactions in the ground state citation needed nbsp Double mutant cycle used by Hunter et al 11 to probe T shaped p stacking interactionsHunter et al applied a more sophisticated chemical double mutant cycle with a hydrogen bonded zipper to the issue of substituent effects in pi stacking interactions 11 This technique has been used to study a multitude of noncovalent interactions The single mutation in this case changing a substituent on an aromatic ring results in secondary effects such as a change in hydrogen bond strength The double mutation quantifies these secondary interactions such that even a weak interaction of interest can be dissected from the array Their results indicate that more electron withdrawing substituents have less repulsive pi stacking interactions Correspondingly this trend was exactly inverted for interactions with pentafluorophenylbenzene which has a quadrupole moment equal in magnitude but opposite in sign as that of benzene 7 The findings provide direct evidence for the Hunter Sanders model However the stacking interactions measured using the double mutant method were surprisingly small and the authors note that the values may not be transferable to other systems In a follow up study Hunter et al verified to a first approximation that the interaction energies of the interacting aromatic rings in a double mutant cycle are dominated by electrostatic effects 12 However the authors note that direct interactions with the ring substituents discussed below also make important contributions Indeed the interplay of these two factors may result in the complicated substituent and geometry dependent behavior of pi stacking interactions Direct interaction model edit The Hunter Sanders model has been criticized by numerous research groups offering contradictory experimental and computational evidence of pi stacking interactions that are not governed primarily by electrostatic effects 13 The clearest experimental evidence against electrostatic substituent effects was reported by Rashkin and Waters 14 They used meta and para substituted N benzyl 2 2 fluorophenyl pyridinium bromides which stack in a parallel displaced conformation as a model system for pi stacking interactions In their system a methylene linker prohibits favorable T shaped interactions As in previous models the relative strength of pi stacking interactions was measured by NMR as the rate of rotation about the biaryl bond as pi stacking interactions are disrupted in the transition state Para substituted rings had small rotational barriers which increased with increasingly electron withdrawing groups consistent with prior findings However meta substituted rings had much larger barriers of rotation despite having nearly identical electron densities in the aromatic ring The authors explain this discrepancy as direct interaction of the edge of hydrogen atoms of one ring with the electronegative substituents on the other ring This claim is supported by chemical shift data of the proton in question citation needed Much of the detailed analyses of the relative contributions of factors in pi stacking have been borne out by computation Sherill and Sinnokrot reported a surprising finding using high level theory that all substituted benzene dimers have more favorable binding interactions than a benzene dimer in the sandwich configuration 15 Later computational work from the Sherill group revealed that the substituent effects for the sandwich configuration are additive which points to a strong influence of dispersion forces and direct interactions between substituents 16 It was noted that interactions between substituted benzenes in the T shaped configuration were more complex Finally Sherill and Sinnokrot argue in their review article that any semblance of a trend based on electron donating or withdrawing substituents can be explained by exchange repulsion and dispersion terms 17 nbsp Houk and Wheeler s 18 computational model of substituent direct interactions in pi stacking Houk and Wheeler also provide compelling computational evidence for the importance of direct interaction in pi stacking 18 In their analysis of substituted benzene dimers in a sandwich conformation they were able to recapitulate their findings using an exceedingly simple model where the substituted benzene Ph X was replaced by H X Remarkably this crude model resulted in the same trend in relative interaction energies and correlated strongly with the values calculated for Ph X This finding suggests that substituent effects in the benzene dimer are due to direct interaction of the substituent with the aromatic ring and that the pi system of the substituted benzene is not involved This latter point is expanded upon below In summary it would seem that the relative contributions of electrostatics dispersion and direct interactions to the substituent effects seen in pi stacking interactions are highly dependent on geometry and experimental design The lack of consensus on the matter may simply reflect the complexity of the issue Requirement of aromaticity editThe conventional understanding of pi stacking involves quadrupole interactions between delocalized electrons in p orbitals In other words aromaticity should be required for this interaction to occur However several groups have provided contrary evidence calling into question whether pi stacking is a unique phenomenon or whether it extends to other neutral closed shell molecules In an experiment not dissimilar from others mentioned above Paliwal and coauthors constructed a molecular torsion balance from an aryl ester with two conformational states 19 The folded state had a well defined pi stacking interaction with a T shaped geometry whereas the unfolded state had no aryl aryl interactions The NMR chemical shifts of the two conformations were distinct and could be used to determine the ratio of the two states which was interpreted as a measure of intramolecular forces The authors report that a preference for the folded state is not unique to aryl esters For example the cyclohexyl ester favored the folded state more so than the phenyl ester and the tert butyl ester favored the folded state by a preference greater than that shown by any aryl ester This suggests that aromaticity is not a strict requirement for favorable interaction with an aromatic ring Other evidence for non aromatic pi stacking interactions results include critical studies in theoretical chemistry explaining the underlying mechanisms of empirical observations Grimme reported that the interaction energies of smaller dimers consisting of one or two rings are very similar for both aromatic and saturated compounds 20 This finding is of particular relevance to biology and suggests that the contribution of pi systems to phenomena such as stacked nucleobases may be overestimated However it was shown that an increased stabilizing interaction is seen for large aromatic dimers As previously noted this interaction energy is highly dependent on geometry Indeed large aromatic dimers are only stabilized relative to their saturated counterparts in a sandwich geometry while their energies are similar in a T shaped interaction nbsp a Substituted naphthalenes and b Homodesmotic dissection of benzene used by Bloom and Wheeler 21 to quantify the effects of delocalization on pi stacking A more direct approach to modeling the role of aromaticity was taken by Bloom and Wheeler 21 The authors compared the interactions between benzene and either 2 methylnaphthalene or its non aromatic isomer 2 methylene 2 3 dihydronaphthalene The latter compound provides a means of conserving the number of p electrons while however removing the effects of delocalization Surprisingly the interaction energies with benzene are higher for the non aromatic compound suggesting that pi bond localization is favorable in pi stacking interactions The authors also considered a homodesmotic dissection of benzene into ethylene and 1 3 butadiene and compared these interactions in a sandwich with benzene Their calculation indicates that the interaction energy between benzene and homodesmotic benzene is higher than that of a benzene dimer in both sandwich and parallel displaced conformations again highlighting the favorability of localized pi bond interactions These results strongly suggest that aromaticity is not required for pi stacking interactions in this model Even in light of this evidence Grimme concludes that pi stacking does indeed exist 20 However he cautions that smaller rings particularly those in T shaped conformations do not behave significantly differently from their saturated counterparts and that the term should be specified for larger rings in stacked conformations which do seem to exhibit a cooperative pi electron effect Applications edit nbsp A fullerene bound in a buckycatcher through aromatic stacking interactions 22 A powerful demonstration of stacking is found in the buckycatcher 22 This molecular tweezer is based on two concave buckybowls with a perfect fit for one convex fullerene molecule Complexation takes place simply by evaporating a toluene solution containing both compounds In solution an association constant of 8600 M 1 is measured based on changes in NMR chemical shifts citation needed nbsp Tacrine bound to acetylcholinesterase PDB 1ACJ A pi stacking interaction between tacrine blue and Trp84 red is proposed Pi stacking is prevalent in protein crystal structures and also contributes to the interactions between small molecules and proteins As a result pi pi and cation pi interactions are important factors in rational drug design 23 One example is the FDA approved acetylcholinesterase AChE inhibitor tacrine which is used in the treatment of Alzheimer s disease Tacrine is proposed to have a pi stacking interaction with the indolic ring of Trp84 and this interaction has been exploited in the rational design of novel AChE inhibitors 24 Addition in pharmacological active compounds edit nbsp Cocaine analog 21b an antagonistSeveral variants of pi coordinated phenyls have even been tested using transition metals for stacking h6 phenyltropanes using cyclopentadienyl and tricarbonyl in place of a benzene Which in the case of the tricarbonyl doubled the compound s affinity for its intended ligand site posited as due to resultant electrostatic influences being more conducive to the target 25 In supramolecular assembly edit nbsp Figure 2 The Stoddart synthesis of 2 catenane p systems are important building blocks in supramolecular assembly because of their versatile noncovalent interactions with various functional groups A notable example of applying p p interactions in supramolecular assembly is the synthesis of catenane The major challenge for the synthesis of catenane is to interlock molecules in a controlled fashion Stoddart and co workers developed a series of systems utilizing the strong p p interactions between electron rich benzene derivatives and electron poor pyridinium rings 26 2 Catanene was synthesized by reacting bis pyridinium A bisparaphenylene 34 crown 10 B and 1 4 bis bromomethyl benzene C Fig 2 The p p interaction between A and B directed the formation of an interlocked template intermediate that was further cyclized by substitution reaction with compound C to generate the 2 catenane product See also editNoncovalent interaction Dispersion chemistry Cation pi interaction Intercalation biochemistry Intercalation chemistry References edit a b c Martinez CR Iverson BL 2012 Rethinking the term pi stacking Chemical Science 3 7 2191 doi 10 1039 c2sc20045g hdl 2152 41033 ISSN 2041 6520 S2CID 95789541 Lewis M Bagwill C Hardebeck L Wireduaah S 2016 Modern Computational Approaches to Understanding Interactions of Aromatics In Johnson DW Hof F eds Aromatic Interactions Frontiers in Knowledge and Application England Royal Society of Chemistry pp 1 17 ISBN 978 1 78262 662 6 a b McGaughey GB Gagne M Rappe AK June 1998 pi Stacking interactions Alive and well in proteins The Journal of Biological Chemistry 273 25 15458 63 doi 10 1074 jbc 273 25 15458 PMID 9624131 Carter Fenk K Herbert JM November 2020 Reinterpreting p stacking Physical Chemistry Chemical Physics 22 43 24870 24886 doi 10 1039 d0cp05039c PMID 33107520 S2CID 225083299 a b c Sinnokrot MO Valeev EF Sherrill CD September 2002 Estimates of the ab initio limit for pi pi interactions the benzene dimer Journal of the American Chemical Society 124 36 10887 10893 doi 10 1021 ja025896h PMID 12207544 a b Huber RG Margreiter MA Fuchs JE von Grafenstein S Tautermann CS Liedl KR Fox T May 2014 Heteroaromatic p stacking energy landscapes Journal of Chemical Information and Modeling 54 5 1371 1379 doi 10 1021 ci500183u PMC 4037317 PMID 24773380 a b Battaglia MR Buckingham AD Williams JH 1981 The electric quadrupole moments of benzene and hexafluorobenzene Chem Phys Lett 78 3 421 423 Bibcode 1981CPL 78 421B doi 10 1016 0009 2614 81 85228 1 Riley KE Hobza P April 2013 On the importance and origin of aromatic interactions in chemistry and biodisciplines Accounts of Chemical Research 46 4 927 936 doi 10 1021 ar300083h PMID 22872015 Hunter CA Sanders JK 1990 The nature of p p Interactions J Am Chem Soc 112 14 5525 5534 doi 10 1021 ja00170a016 Cozzi F Cinquini M Annuziata R Siegel JS 1993 Dominance of polar pi Over charge transfer effects in stacked phenyl interactions J Am Chem Soc 115 12 5330 5331 doi 10 1021 ja00065a069 a b Cockroft SL Hunter CA Lawson KR Perkins J Urch CJ June 2005 Electrostatic control of aromatic stacking interactions Journal of the American Chemical Society 127 24 8594 8595 doi 10 1021 ja050880n PMID 15954755 Cockroft SL Perkins J Zonta C Adams H Spey SE Low CM et al April 2007 Substituent effects on aromatic stacking interactions Organic amp Biomolecular Chemistry 5 7 1062 1080 doi 10 1039 b617576g PMID 17377660 S2CID 37409177 Martinez Chelsea R Iverson Brent L 2012 Rethinking the term pi stacking Chemical Science 3 7 2191 doi 10 1039 C2SC20045G hdl 2152 41033 Rashkin MJ Waters ML March 2002 Unexpected substituent effects in offset pi pi stacked interactions in water Journal of the American Chemical Society 124 9 1860 1861 doi 10 1021 ja016508z PMID 11866592 Sinnokrot MO Sherrill CD 2003 Unexpected Substituent Effects in Face to Face p Stacking Interactions J Phys Chem A 107 41 8377 8379 Bibcode 2003JPCA 107 8377S doi 10 1021 jp030880e Ringer AL Sinnokrot MO Lively RP Sherrill CD May 2006 The effect of multiple substituents on sandwich and T shaped pi pi interactions Chemistry A European Journal 12 14 3821 3828 doi 10 1002 chem 200501316 PMID 16514687 Sinnokrot MO Sherrill CD September 2006 High accuracy quantum mechanical studies of pi pi interactions in benzene dimers The Journal of Physical Chemistry A 110 37 10656 10668 Bibcode 2006JPCA 11010656S doi 10 1021 jp0610416 PMID 16970354 a b Wheeler SE Houk KN August 2008 Substituent effects in the benzene dimer are due to direct interactions of the substituents with the unsubstituted benzene Journal of the American Chemical Society 130 33 10854 10855 doi 10 1021 ja802849j PMC 2655233 PMID 18652453 Paliwal S Geib S Wilcox CS 1994 Molecular Torsion Balance for Weak Molecular Recognition Forces Effects of Tilted T Edge to Face Aromatic Interactions on Conformational Selection and Solid State Structure J Am Chem Soc 116 10 4497 4498 doi 10 1021 ja00089a057 a b Grimme S 2008 Do special noncovalent pi pi stacking interactions really exist Angewandte Chemie 47 18 3430 3434 doi 10 1002 anie 200705157 PMID 18350534 a b Bloom JW Wheeler SE 2011 Taking the Aromaticity out of Aromatic Interactions Angew Chem 123 34 7993 7995 Bibcode 2011AngCh 123 7993B doi 10 1002 ange 201102982 a b Sygula A Fronczek FR Sygula R Rabideau PW Olmstead MM April 2007 A double concave hydrocarbon buckycatcher Journal of the American Chemical Society 129 13 3842 3843 doi 10 1021 ja070616p PMID 17348661 S2CID 25154754 Babine RE Bender SL August 1997 Molecular Recognition of Proteinminus signLigand Complexes Applications to Drug Design Chemical Reviews 97 5 1359 1472 doi 10 1021 cr960370z PMID 11851455 da Silva CH Campo VL Carvalho I Taft CA October 2006 Molecular modeling docking and ADMET studies applied to the design of a novel hybrid for treatment of Alzheimer s disease Journal of Molecular Graphics amp Modelling 25 2 169 175 doi 10 1016 j jmgm 2005 12 002 PMID 16413803 Singh S March 2000 Chemistry design and structure activity relationship of cocaine antagonists Chemical Reviews 100 3 925 1024 doi 10 1021 cr9700538 PMID 11749256 Ashton PR Goodnow TT Kaifer AE Reddington MV Slawin AM Spencer N et al 1989 A 2 Catenane Made to Order J Angew Chem Int Ed 28 10 1396 1399 doi 10 1002 anie 198913961 External links editLuo R Gilson HS Potter MJ Gilson MK January 2001 The physical basis of nucleic acid base stacking in water Biophysical Journal 80 1 140 148 Bibcode 2001BpJ 80 140L doi 10 1016 S0006 3495 01 76001 8 PMC 1301220 PMID 11159389 Larry Wolf 2011 p p p Stacking interactions origin and modulation Retrieved from https en wikipedia org w index php title Stacking chemistry amp oldid 1188162967, wikipedia, wiki, book, books, library,

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