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Juliá–Colonna epoxidation

March 19, 2024

The Juliá–Colonna epoxidation is an asymmetric poly-leucine catalyzed nucleophilic epoxidation of electron deficient olefins in a triphasic system. The reaction was reported by Sebastian Juliá at the Chemical Institute of Sarriá in 1980,[1] with further elaboration by both Juliá and Stefano Colonna (Istituto di Chimica Industriale dell'Università, Milan, Italy).[2]

The Juliá–Colonna Epoxidation of a chalcone proceeds with poly-L-leucine and hydrogen peroxide in generic triphasic conditions. Image adapted from Juliá et al.[2]

In the original triphasic protocol, the chalcone substrate is soluble in the organic phase, generally toluene or carbon tetrachloride. The alkaline hydrogen peroxide oxidant is soluble primarily in the aqueous phase, and the reaction occurs at the insoluble polymer layer at the interface of the two phases. Alternative biphasic and monophasic protocols have been developed with increased substrate accessibility and reaction rate.[3][4]

The efficient enantioselective catalytic epoxidation under mild conditions is of great synthetic utility. Not only are epoxides effective synthons for a range of transformations, they have a significant presence in natural products structures. Furthermore, the reaction has been effectively scaled up to industrially useful levels, with work conducted notably by Bayer and Evonik. Finally, the enzyme-like activity of the poly-amino acid segments is suggestive of a role of the reaction in the prebiotic origin of life.[5][6]

Reaction mechanism edit

The Juliá–Colonna epoxidation is an asymmetric nucleophilic epoxidation of electron-deficient olefins such as α,β-unsaturated ketones. The general mechanism shown in Figure 2 applies to all nucleophilic epoxidations but is controlled in this reaction by the poly-leucine catalyst.

 
Figure 2: The generic mechanism for nucleophilic epoxidation of an electron-deficient olefin indicates that the reaction proceeds through a resonance stabilized peroxide enolate intermediate.

The hydroperoxide anion and chalcone assemble in a complex with the poly-leucine catalyst before reacting to form a peroxide enolate intermediate. The intermediate subsequently closes, as controlled by the catalyst structure, to form the epoxide product stereoselectively.

Ternary complex formation edit

 
Figure 3: The Juliá–Colonna Epoxidation proceeds by random steady-state formation of a ternary complex prior to reaction to form the peroxide enolate intermediate and final epoxide product. Image adapted from Carrea et al.[5]
 
Figure 4: Hydrogen bonding with the N-terminal residues stabilizes the peroxide enolate intermediate and orients the structure for ring closing with hydroxide displacement. The chalcone peroxide enolate is shown in green with hydrogen bonding interactions in red. The amino acid side-chains are omitted for clarity. Numbering refers to the amino group of each amino acid in the 7-mer, beginning at the N-terminus. Image inspired by Kelly et al.[7]

The poly-leucine strands demonstrate enzyme-like kinetics with a first-order dependence on and eventual saturation with both the hydroperoxide anion (KM= 30 mM) and the olefin substrate (KM=110 mM.) Kinetic study suggests that the reaction proceeds by random steady-state formation of a ternary (polyleucine+hydroperoxide anion+olefin) complex. Both substrates must bind prior to reaction, and while either may bind first, initial hydroperoxide binding is kinetically preferred. The rapid equilibrium enabling complex formation is followed by the rate-limiting formation of the peroxide enolate (Figure 3).[5][8]

Mechanistic origin of stereoselectivity edit

All of the reactants associate with the polyleucine catalyst prior to reaction to form the hydroperoxide enolate intermediate. The catalyst orients the reactants and, even more significantly, the peroxide enolate intermediate by a series of hydrogen bonding interactions with the four N-terminal amino groups in the poly-leucine α-helix. While other models have been proposed,[9] computations by Kelly et al. have suggested that the NH-2, NH-3, and NH-4 form an isosceles triangle available for hydrogen bonding as an intermediate-stabilizing oxyanion hole. While olefin binding to either the endo or exo face of the helix is sterically allowed, only endo binding orients the NH-4 group to bind with the hydroperoxide moiety allowing for hydroxide displacement in the final reaction step (Figure 4).[7]

Catalyst edit

Poly-amino acid selection edit

Enantioselectivity is maximized by poly-amino acid sequences containing the greatest α-helical content; these include poly-leucine and poly-alanine.[1] Both poly-L- and poly-D-amino acids are available and cause the opposite stereoinduction.[10]

Catalyst generation edit

 
Figure 5: The original poly-leucine catalysts for the Juliá–Colonna Epoxidation were formed by reacting leucine-N-carboxyanhydrides with an initiator such as n-butylamine.


The original poly-leucine catalysts were formed by reacting leucine-N-carboxyanhydrides with an initiator such as an amine, an alcohol or water (Figure 5).[2] In triphasic systems, the polymer catalyst must be soaked in the organic solvent and peroxide solution to generate a gel prior to reaction.[11] – Especially in biphasic systems, reaction time may be reduced and enantioselectivity increased by activating the catalyst with NaOH prior to reaction. Furthermore, in biphasic systems the polymer may be immobilized on polystyrene, polyethylene glycol (PEG), or silica gel and formed into a paste.[4]

Catalyst secondary structure edit

The active component of the catalyst assumes an α-helical structure where the four to five N-terminal residues are actively involved in catalysis. While active catalysts have been generated from scalemic leucine, consistent enantiomeric content must be maintained through the N-terminal region to give appropriate handedness to the structure.[10] While the greatest enantioselectivity was originally observed when n=30 residues,[2] a 10-mer Leucine polypeptide is of sufficient length to provide significant enantioselectivity[10] Following improvement of the original procedure, greater enantioselectivity has been observed for lower molecular weight polymers, presumably due to the greater number of N-termini available per mass used.[4]

Scope edit

The Juliá–Colonna epoxidation of electron-deficient olefins was originally demonstrated with chalcones, but it was soon extended to other systems with electron withdrawing moieties such as α,β-unsaturated ketones, esters, and amides.[1][2] The reaction has also demonstrated efficiency with sulfone substrates, and the scope of the reaction is being expanded with further methodological investigation.[12]

Several classes of substrates, however, are not suitable for the Juliá–Colonna Epoxidation. These include:[10]

  • compounds sensitive to hydroxide.
  • compounds with acidic protons on the α or α’ positions.
  • electron rich olefins.

The nucleophilic epoxidation is naturally complementary in scope to electrophilic epoxidations such as the Sharpless epoxidation and Jacobsen epoxidation.

Stereoselectivity edit

Catalyst structure edit

The stereoinduction of the Juliá–Colonna epoxidation is dependent on the α-helical secondary structure of the poly-leucine catalyst. While the consistent stereochemistry of the N-terminal amino acids is necessary for this induction, even a 10-mer leucine polypeptide is of sufficient length to provide significant enantioselectivity.[10]

Chiral amplification by scalemic catalysts edit

This dependence solely on the N-terminal region of the helix is most pronounced in enantioselective stereoinduction by scalemic catalysts. Even a 40% enantiomeric excess of L vs. D-leucine in catalyst formation can yield the same enantiomeric enriched epoxide as the enantiopure catalyst. The relationship between catalyst and product enantiopurity can be closely approximated with a Bernoullian statistical model: een=(Ln-Dn)/(Ln+Dn) where L and D are the proportions of L- and D-leucine used to generate the catalytic polymers and n is the length of the catalytic component.[5][6]

Chiral amino acids, including leucine, have been generated in electrical discharge experiments designed to mimic the prebiotic conditions on Earth, and they have been found in scalemic mixtures in meteorites. It has been suggested that poly-amino acid fragments analogous to the Juliá–Colonna catalyst may have been initiated by imidazole or cyanide derivatives, and the resulting fragments may have played a catalytic role in the origin of enantiomeric enrichment ubiquitous in life today.[5]

Variations edit

Silica-grafted catalysts edit

Silica-grafted polyleucine has been shown to effectively catalyze epoxidation of α,β-unsaturated aromatic ketones. The silica graft allows for the catalyst to be easily recovered with only mild loss of activity and is particularly useful for scale-up reactions.[13]

Biphasic (non-aqueous) reaction conditions edit

For the alternative biphasic protocol, the olefin substrate is dissolved in tetrahydrofuran (THF) along with the urea hydrogen peroxide (UHP) oxidant and a tertiary amine base such as 8-diazabicyclo[5.4.0]undec-7-ene (DBU.) The immobilized polymer catalyst forms a paste which serves as the reaction site. The two phase reaction conditions extended the range of enones to which the reaction could be applied.[3]

Monophasic reaction conditions with PEG-immobilized polyleucine edit

A soluble initiator O,O′-bis(2-aminoethyl)polyethylene glycol (diaminoPEG) for poly-leucine assembly was utilized to generate a THF-soluble triblock polymer. Utilization of this catalyst in homogeneous reaction conditions enabled marked extension of the methodology to α,β-unsaturated ketones, dienes, and bis-dienes.[4]

Phase transfer co-catalysis edit

Addition of tetrabutylammonium bromide as a phase transfer catalyst dramatically increases the rate of reaction. The co-catalyst is presumed to increase the concentration of the peroxide oxidant in the organic phase enabling more efficient access to the reactive ternary complex.[14] These conditions were developed for application to two phase systems but also function for three phase systems and have been utilized up to the 100g scale[5][12]

Scale-up edit

Immobilized catalysts have been used in membrane reactors and are being investigated for application to continuous flow fixed bed reactors.[11]

Applications to synthesis edit

Total synthesis of Diltiazem edit

Adger et al. utilized the biphasic Juliá–Colonna epoxidation with immobilized poly-L-leucine (I-PLL) and urea hydrogen peroxide (UHP), and 8-diazabicyclo[5.4.0]undec-7-ene (DBU) as the key step in the efficient synthesis of Diltiazem (Figure 6.) Diltiazem is a commercially available pharmaceutical which acts as a calcium channel blocker.[11]

 
Figure 6: The Juliá–Colonna Epoxidation has been applied to the Total Synthesis of Diltiazem.[11]

Total synthesis of (+)-clausenamide edit

Cappi et al. utilized the Juliá–Colonna epoxidation with PEG-immobilized poly-L-leucine (PEG-PLL) and DABCO hydrogen peroxide (DABCO-H2O2) or urea hydrogen peroxide (UHP) in a miniature fixed-bed continuous flow reactor system (Figure 7.) This protocol was exploited to synthesize (+)-clausenamide as a proof of concept in the development of the novel reaction protocol; (+)-clausenamide exhibits anti-amnesiac and hepatoprotective activity.[15]

 
Figure 7: The Juliá–Colonna Epoxidation has been applied to the Total Synthesis of (+)-Clausenamide.[15]

Total synthesis of (+)-goniotriol 7, (+)-goniofufurone 8, (+)-8-acetylgoniotriol 9 and gonio-pypyrone edit

Chen et al. utilized the biphasic Juliá–Colonna Epoxidation protocol with urea hydrogen peroxide (UHP), poly-L-leucine (PLL), and 8-diazabicyclo[5.4.0]undec-7-ene (DBU) as a key step in the synthesis of a family of styryl lactones isolated from Goniothalamus giganteus (Figure 8.) These compounds, including (+)-goniotriol 7, (+)-goniofufurone 8, (+)-8-acetylgoniotriol 9 and gonio-pypyrone, have demonstrated cytotoxic activity against human tumor cells.[16]

 
Figure 8: The Juliá–Colonna Epoxidation has been applied to the Total Synthesis of (+)-goniotriol 7, (+)-goniofufurone 8, (+)-8-acetylgoniotriol 9 and gonio-pypyrone.[16]

See also edit

References edit

  1. ^ a b c Juliá, S. N.; Masana, J.; Vega, J. C. (1980). ""Synthetic Enzymes". Highly Stereoselective Epoxidation of Chalcone in a Triphasic Toluene-Water-Poly\(S)-alanine] System". Angewandte Chemie International Edition in English. 19 (11): 929. doi:10.1002/anie.198009291.
  2. ^ a b c d e Juliá, Sebastián; Guixer, Joan; Masana, Jaume; Rocas, José; Colonna, Stefano; Annuziata, Rita; Molinari, Henriette (1982). "Synthetic enzymes. Part 2. Catalytic asymmetric epoxidation by means of polyamino-acids in a triphase system". J. Chem. Soc., Perkin Trans. 1: 1317–1324. doi:10.1039/P19820001317.
  3. ^ a b Allen, Joanne V.; Bergeron, Sophie; Griffiths, Matthew J.; Mukherjee, Shubhasish; Roberts, Stanley M.; Williamson, Natalie M.; Wu, L. Eduardo (1998). "Juliá–Colonna asymmetric epoxidation reactions under non-aqueous conditions: rapid, highly regio- and stereo-selective transformations using a cheap, recyclable catalyst". J. Chem. Soc., Perkin Trans. 1 (19): 3171–3180. doi:10.1039/A805407J.
  4. ^ a b c d Flood, Robert W.; Geller, Thomas P.; Petty, Sarah A.; Roberts, Stanley M.; Skidmore, John; Volk, Martin (2001). "Efficient Asymmetric Epoxidation of α,β-Unsaturated Ketones Using a Soluble Triblock Polyethylene Glycol−Polyamino Acid Catalyst". Org. Lett. 3 (5): 683–6. doi:10.1021/ol007005l. PMID 11259036.
  5. ^ a b c d e f Carrea, G; Colonna, S; Kelly, D; Lazcano, A; Ottolina, G; Roberts, S (2005). "Polyamino acids as synthetic enzymes: mechanism, applications and relevance to prebiotic catalysis". Trends in Biotechnology. 23 (10): 507–13. doi:10.1016/j.tibtech.2005.07.010. PMID 16085328.
  6. ^ a b Kelly, David R.; Meek, Alastair; Roberts, Stanley M. (2004). "Chiral amplification by polypeptides and its relevance to prebiotic catalysis". Chem. Comm. (18): 2021–2. doi:10.1039/B404379K. PMID 15367955.
  7. ^ a b Kelly, D. R.; Roberts, S. M., The mechanism of polyleucine catalysed asymmetric epoxidation". Chem. Comm. 2004, (18), 2018-2020. doi:10.1039/B404390C
  8. ^ Carrea, G.; Colonna, S.; Meek, A. D.; Ottolina, G.; Roberts, S. M., "Kinetics of chalcone oxidation by peroxide anion catalysed by poly-L-leucine". Chem. Comm. 2004, (12), 1412-1413. doi:10.1039/B401497A
  9. ^ Berkessel, A.; Gasch, N.; Glaubitz, K.; Koch, C., "Highly enantioselective enone epoxidation catalyzed by short solid phase-bound peptides: Dominant role of peptide helicity". Org. Lett. 2001, 3 (24), 3839–3842. doi:10.1021/ol0166451
  10. ^ a b c d e Bentley, P. A.; Cappi, M. W.; Flood, R. W.; Roberts, S. M.; Smith, J. A., Towards a mechanistic insight into the Julia-Colonna asymmetric epoxidation of α,β-unsaturated ketones using discrete lengths of poly-leucine. Tetrahedron Lett. 1998, 39 (50), 9297–9300. doi:10.1016/S0040-4039(98)02090-5
  11. ^ a b c d Adger, B. M.; Barkley, J. V.; Bergeron, S.; Cappi, M. W.; Flowerdew, B. E.; Jackson, M. P.; McCague, R.; Nugent, T. C.; Roberts, S. M., "Improved procedure for Julia–Colonna asymmetric epoxidation of α,β-unsaturated ketones: total synthesis of diltiazem and Taxol (TM) side-chain". J. Chem. Soc.-Perkin Trans. 1 1997, (23), 3501–3507. doi:10.1039/A704413E
  12. ^ a b Lopez-Pedrosa, J. M.; Pitts, M. R.; Roberts, S. M.; Saminathan, S.; Whittall, J., "Asymmetric epoxidation of some arylalkenyl sulfones using a modified Julia–Colonna procedure". Tetrahedron Lett. 2004, 45 (26), 5073–5075. doi:10.1016/j.tetlet.2004.04.190
  13. ^ Yi, H.; Zou, G.; Li, Q.; Chen, Q.; Tang, J.; He, M. Y., "Asymmetric epoxidation of alpha,beta-unsaturated ketones catalyzed by silica-grafted poly-(L)-leucine catalysts". Tetrahedron Lett. 2005, 46 (34), 5665–5668. doi:10.1016/j.tetlet.2005.06.096
  14. ^ Geller, T.; Gerlach, A.; Kruger, C. M.; Militzer, H. C., "Novel conditions for the Julia–Colonna epoxidation reaction providing efficient access to chiral, nonracemic epoxides". Tetrahedron Lett. 2004, 45 (26), 5065–5067. doi:10.1016/j.tetlet.2004.04.188
  15. ^ a b Cappi, M. W.; Chen, W. P.; Flood, R. W.; Liao, Y. W.; Roberts, S. M.; Skidmore, J.; Smith, J. A.; Williamson, N. M., "New procedures for the –Colonna asymmetric epoxidation: synthesis of (+)-clausenamide". Chem. Comm. 1998, (10), 1159-1160. doi:10.1039/A801450G
  16. ^ a b Chen, W. P.; Roberts, S. M., "Julia–Colonna asymmetric epoxidation of furyl styryl ketone as a route to intermediates to naturally-occurring styryl lactones". J. Chem. Soc.-Perkin Trans. 1 1999, (2), 103–105. doi:10.1039/A808436J

External links edit

March 19, 2024
juliá, colonna, epoxidation, asymmetric, poly, leucine, catalyzed, nucleophilic, epoxidation, electron, deficient, olefins, triphasic, system, reaction, reported, sebastian, juliá, chemical, institute, sarriá, 1980, with, further, elaboration, both, juliá, ste. The Julia Colonna epoxidation is an asymmetric poly leucine catalyzed nucleophilic epoxidation of electron deficient olefins in a triphasic system The reaction was reported by Sebastian Julia at the Chemical Institute of Sarria in 1980 1 with further elaboration by both Julia and Stefano Colonna Istituto di Chimica Industriale dell Universita Milan Italy 2 The Julia Colonna Epoxidation of a chalcone proceeds with poly L leucine and hydrogen peroxide in generic triphasic conditions Image adapted from Julia et al 2 In the original triphasic protocol the chalcone substrate is soluble in the organic phase generally toluene or carbon tetrachloride The alkaline hydrogen peroxide oxidant is soluble primarily in the aqueous phase and the reaction occurs at the insoluble polymer layer at the interface of the two phases Alternative biphasic and monophasic protocols have been developed with increased substrate accessibility and reaction rate 3 4 The efficient enantioselective catalytic epoxidation under mild conditions is of great synthetic utility Not only are epoxides effective synthons for a range of transformations they have a significant presence in natural products structures Furthermore the reaction has been effectively scaled up to industrially useful levels with work conducted notably by Bayer and Evonik Finally the enzyme like activity of the poly amino acid segments is suggestive of a role of the reaction in the prebiotic origin of life 5 6 Contents 1 Reaction mechanism 1 1 Ternary complex formation 1 2 Mechanistic origin of stereoselectivity 2 Catalyst 2 1 Poly amino acid selection 2 2 Catalyst generation 2 3 Catalyst secondary structure 3 Scope 4 Stereoselectivity 4 1 Catalyst structure 4 2 Chiral amplification by scalemic catalysts 5 Variations 5 1 Silica grafted catalysts 5 2 Biphasic non aqueous reaction conditions 5 3 Monophasic reaction conditions with PEG immobilized polyleucine 5 4 Phase transfer co catalysis 5 5 Scale up 6 Applications to synthesis 6 1 Total synthesis of Diltiazem 6 2 Total synthesis of clausenamide 6 3 Total synthesis of goniotriol 7 goniofufurone 8 8 acetylgoniotriol 9 and gonio pypyrone 7 See also 8 References 9 External linksReaction mechanism editThe Julia Colonna epoxidation is an asymmetric nucleophilic epoxidation of electron deficient olefins such as a b unsaturated ketones The general mechanism shown in Figure 2 applies to all nucleophilic epoxidations but is controlled in this reaction by the poly leucine catalyst nbsp Figure 2 The generic mechanism for nucleophilic epoxidation of an electron deficient olefin indicates that the reaction proceeds through a resonance stabilized peroxide enolate intermediate The hydroperoxide anion and chalcone assemble in a complex with the poly leucine catalyst before reacting to form a peroxide enolate intermediate The intermediate subsequently closes as controlled by the catalyst structure to form the epoxide product stereoselectively Ternary complex formation edit nbsp Figure 3 The Julia Colonna Epoxidation proceeds by random steady state formation of a ternary complex prior to reaction to form the peroxide enolate intermediate and final epoxide product Image adapted from Carrea et al 5 nbsp Figure 4 Hydrogen bonding with the N terminal residues stabilizes the peroxide enolate intermediate and orients the structure for ring closing with hydroxide displacement The chalcone peroxide enolate is shown in green with hydrogen bonding interactions in red The amino acid side chains are omitted for clarity Numbering refers to the amino group of each amino acid in the 7 mer beginning at the N terminus Image inspired by Kelly et al 7 The poly leucine strands demonstrate enzyme like kinetics with a first order dependence on and eventual saturation with both the hydroperoxide anion KM 30 mM and the olefin substrate KM 110 mM Kinetic study suggests that the reaction proceeds by random steady state formation of a ternary polyleucine hydroperoxide anion olefin complex Both substrates must bind prior to reaction and while either may bind first initial hydroperoxide binding is kinetically preferred The rapid equilibrium enabling complex formation is followed by the rate limiting formation of the peroxide enolate Figure 3 5 8 Mechanistic origin of stereoselectivity edit All of the reactants associate with the polyleucine catalyst prior to reaction to form the hydroperoxide enolate intermediate The catalyst orients the reactants and even more significantly the peroxide enolate intermediate by a series of hydrogen bonding interactions with the four N terminal amino groups in the poly leucine a helix While other models have been proposed 9 computations by Kelly et al have suggested that the NH 2 NH 3 and NH 4 form an isosceles triangle available for hydrogen bonding as an intermediate stabilizing oxyanion hole While olefin binding to either the endo or exo face of the helix is sterically allowed only endo binding orients the NH 4 group to bind with the hydroperoxide moiety allowing for hydroxide displacement in the final reaction step Figure 4 7 Catalyst editPoly amino acid selection edit Enantioselectivity is maximized by poly amino acid sequences containing the greatest a helical content these include poly leucine and poly alanine 1 Both poly L and poly D amino acids are available and cause the opposite stereoinduction 10 Catalyst generation edit nbsp Figure 5 The original poly leucine catalysts for the Julia Colonna Epoxidation were formed by reacting leucine N carboxyanhydrides with an initiator such as n butylamine The original poly leucine catalysts were formed by reacting leucine N carboxyanhydrides with an initiator such as an amine an alcohol or water Figure 5 2 In triphasic systems the polymer catalyst must be soaked in the organic solvent and peroxide solution to generate a gel prior to reaction 11 Especially in biphasic systems reaction time may be reduced and enantioselectivity increased by activating the catalyst with NaOH prior to reaction Furthermore in biphasic systems the polymer may be immobilized on polystyrene polyethylene glycol PEG or silica gel and formed into a paste 4 Catalyst secondary structure edit The active component of the catalyst assumes an a helical structure where the four to five N terminal residues are actively involved in catalysis While active catalysts have been generated from scalemic leucine consistent enantiomeric content must be maintained through the N terminal region to give appropriate handedness to the structure 10 While the greatest enantioselectivity was originally observed when n 30 residues 2 a 10 mer Leucine polypeptide is of sufficient length to provide significant enantioselectivity 10 Following improvement of the original procedure greater enantioselectivity has been observed for lower molecular weight polymers presumably due to the greater number of N termini available per mass used 4 Scope editThe Julia Colonna epoxidation of electron deficient olefins was originally demonstrated with chalcones but it was soon extended to other systems with electron withdrawing moieties such as a b unsaturated ketones esters and amides 1 2 The reaction has also demonstrated efficiency with sulfone substrates and the scope of the reaction is being expanded with further methodological investigation 12 Several classes of substrates however are not suitable for the Julia Colonna Epoxidation These include 10 compounds sensitive to hydroxide compounds with acidic protons on the a or a positions electron rich olefins The nucleophilic epoxidation is naturally complementary in scope to electrophilic epoxidations such as the Sharpless epoxidation and Jacobsen epoxidation Stereoselectivity editCatalyst structure edit The stereoinduction of the Julia Colonna epoxidation is dependent on the a helical secondary structure of the poly leucine catalyst While the consistent stereochemistry of the N terminal amino acids is necessary for this induction even a 10 mer leucine polypeptide is of sufficient length to provide significant enantioselectivity 10 Chiral amplification by scalemic catalysts edit This dependence solely on the N terminal region of the helix is most pronounced in enantioselective stereoinduction by scalemic catalysts Even a 40 enantiomeric excess of L vs D leucine in catalyst formation can yield the same enantiomeric enriched epoxide as the enantiopure catalyst The relationship between catalyst and product enantiopurity can be closely approximated with a Bernoullian statistical model een Ln Dn Ln Dn where L and D are the proportions of L and D leucine used to generate the catalytic polymers and n is the length of the catalytic component 5 6 Chiral amino acids including leucine have been generated in electrical discharge experiments designed to mimic the prebiotic conditions on Earth and they have been found in scalemic mixtures in meteorites It has been suggested that poly amino acid fragments analogous to the Julia Colonna catalyst may have been initiated by imidazole or cyanide derivatives and the resulting fragments may have played a catalytic role in the origin of enantiomeric enrichment ubiquitous in life today 5 Variations editSilica grafted catalysts edit Silica grafted polyleucine has been shown to effectively catalyze epoxidation of a b unsaturated aromatic ketones The silica graft allows for the catalyst to be easily recovered with only mild loss of activity and is particularly useful for scale up reactions 13 Biphasic non aqueous reaction conditions edit For the alternative biphasic protocol the olefin substrate is dissolved in tetrahydrofuran THF along with the urea hydrogen peroxide UHP oxidant and a tertiary amine base such as 8 diazabicyclo 5 4 0 undec 7 ene DBU The immobilized polymer catalyst forms a paste which serves as the reaction site The two phase reaction conditions extended the range of enones to which the reaction could be applied 3 Monophasic reaction conditions with PEG immobilized polyleucine edit A soluble initiator O O bis 2 aminoethyl polyethylene glycol diaminoPEG for poly leucine assembly was utilized to generate a THF soluble triblock polymer Utilization of this catalyst in homogeneous reaction conditions enabled marked extension of the methodology to a b unsaturated ketones dienes and bis dienes 4 Phase transfer co catalysis edit Addition of tetrabutylammonium bromide as a phase transfer catalyst dramatically increases the rate of reaction The co catalyst is presumed to increase the concentration of the peroxide oxidant in the organic phase enabling more efficient access to the reactive ternary complex 14 These conditions were developed for application to two phase systems but also function for three phase systems and have been utilized up to the 100g scale 5 12 Scale up edit Immobilized catalysts have been used in membrane reactors and are being investigated for application to continuous flow fixed bed reactors 11 Applications to synthesis editTotal synthesis of Diltiazem edit Adger et al utilized the biphasic Julia Colonna epoxidation with immobilized poly L leucine I PLL and urea hydrogen peroxide UHP and 8 diazabicyclo 5 4 0 undec 7 ene DBU as the key step in the efficient synthesis of Diltiazem Figure 6 Diltiazem is a commercially available pharmaceutical which acts as a calcium channel blocker 11 nbsp Figure 6 The Julia Colonna Epoxidation has been applied to the Total Synthesis of Diltiazem 11 Total synthesis of clausenamide edit Cappi et al utilized the Julia Colonna epoxidation with PEG immobilized poly L leucine PEG PLL and DABCO hydrogen peroxide DABCO H2O2 or urea hydrogen peroxide UHP in a miniature fixed bed continuous flow reactor system Figure 7 This protocol was exploited to synthesize clausenamide as a proof of concept in the development of the novel reaction protocol clausenamide exhibits anti amnesiac and hepatoprotective activity 15 nbsp Figure 7 The Julia Colonna Epoxidation has been applied to the Total Synthesis of Clausenamide 15 Total synthesis of goniotriol 7 goniofufurone 8 8 acetylgoniotriol 9 and gonio pypyrone edit Chen et al utilized the biphasic Julia Colonna Epoxidation protocol with urea hydrogen peroxide UHP poly L leucine PLL and 8 diazabicyclo 5 4 0 undec 7 ene DBU as a key step in the synthesis of a family of styryl lactones isolated from Goniothalamus giganteus Figure 8 These compounds including goniotriol 7 goniofufurone 8 8 acetylgoniotriol 9 and gonio pypyrone have demonstrated cytotoxic activity against human tumor cells 16 nbsp Figure 8 The Julia Colonna Epoxidation has been applied to the Total Synthesis of goniotriol 7 goniofufurone 8 8 acetylgoniotriol 9 and gonio pypyrone 16 See also editPrilezhaev reaction Jorgensen epoxidation Asymmetric nucleophilic epoxidationReferences edit a b c Julia S N Masana J Vega J C 1980 Synthetic Enzymes Highly Stereoselective Epoxidation of Chalcone in a Triphasic Toluene Water Poly S alanine System Angewandte Chemie International Edition in English 19 11 929 doi 10 1002 anie 198009291 a b c d e Julia Sebastian Guixer Joan Masana Jaume Rocas Jose Colonna Stefano Annuziata Rita Molinari Henriette 1982 Synthetic enzymes Part 2 Catalytic asymmetric epoxidation by means of polyamino acids in a triphase system J Chem Soc Perkin Trans 1 1317 1324 doi 10 1039 P19820001317 a b Allen Joanne V Bergeron Sophie Griffiths Matthew J Mukherjee Shubhasish Roberts Stanley M Williamson Natalie M Wu L Eduardo 1998 Julia Colonna asymmetric epoxidation reactions under non aqueous conditions rapid highly regio and stereo selective transformations using a cheap recyclable catalyst J Chem Soc Perkin Trans 1 19 3171 3180 doi 10 1039 A805407J a b c d Flood Robert W Geller Thomas P Petty Sarah A Roberts Stanley M Skidmore John Volk Martin 2001 Efficient Asymmetric Epoxidation of a b Unsaturated Ketones Using a Soluble Triblock Polyethylene Glycol Polyamino Acid Catalyst Org Lett 3 5 683 6 doi 10 1021 ol007005l PMID 11259036 a b c d e f Carrea G Colonna S Kelly D Lazcano A Ottolina G Roberts S 2005 Polyamino acids as synthetic enzymes mechanism applications and relevance to prebiotic catalysis Trends in Biotechnology 23 10 507 13 doi 10 1016 j tibtech 2005 07 010 PMID 16085328 a b Kelly David R Meek Alastair Roberts Stanley M 2004 Chiral amplification by polypeptides and its relevance to prebiotic catalysis Chem Comm 18 2021 2 doi 10 1039 B404379K PMID 15367955 a b Kelly D R Roberts S M The mechanism of polyleucine catalysed asymmetric epoxidation Chem Comm 2004 18 2018 2020 doi 10 1039 B404390C Carrea G Colonna S Meek A D Ottolina G Roberts S M Kinetics of chalcone oxidation by peroxide anion catalysed by poly L leucine Chem Comm 2004 12 1412 1413 doi 10 1039 B401497A Berkessel A Gasch N Glaubitz K Koch C Highly enantioselective enone epoxidation catalyzed by short solid phase bound peptides Dominant role of peptide helicity Org Lett 2001 3 24 3839 3842 doi 10 1021 ol0166451 a b c d e Bentley P A Cappi M W Flood R W Roberts S M Smith J A Towards a mechanistic insight into the Julia Colonna asymmetric epoxidation of a b unsaturated ketones using discrete lengths of poly leucine Tetrahedron Lett 1998 39 50 9297 9300 doi 10 1016 S0040 4039 98 02090 5 a b c d Adger B M Barkley J V Bergeron S Cappi M W Flowerdew B E Jackson M P McCague R Nugent T C Roberts S M Improved procedure for Julia Colonna asymmetric epoxidation of a b unsaturated ketones total synthesis of diltiazem and Taxol TM side chain J Chem Soc Perkin Trans 1 1997 23 3501 3507 doi 10 1039 A704413E a b Lopez Pedrosa J M Pitts M R Roberts S M Saminathan S Whittall J Asymmetric epoxidation of some arylalkenyl sulfones using a modified Julia Colonna procedure Tetrahedron Lett 2004 45 26 5073 5075 doi 10 1016 j tetlet 2004 04 190 Yi H Zou G Li Q Chen Q Tang J He M Y Asymmetric epoxidation of alpha beta unsaturated ketones catalyzed by silica grafted poly L leucine catalysts Tetrahedron Lett 2005 46 34 5665 5668 doi 10 1016 j tetlet 2005 06 096 Geller T Gerlach A Kruger C M Militzer H C Novel conditions for the Julia Colonna epoxidation reaction providing efficient access to chiral nonracemic epoxides Tetrahedron Lett 2004 45 26 5065 5067 doi 10 1016 j tetlet 2004 04 188 a b Cappi M W Chen W P Flood R W Liao Y W Roberts S M Skidmore J Smith J A Williamson N M New procedures for the Colonna asymmetric epoxidation synthesis of clausenamide Chem Comm 1998 10 1159 1160 doi 10 1039 A801450G a b Chen W P Roberts S M Julia Colonna asymmetric epoxidation of furyl styryl ketone as a route to intermediates to naturally occurring styryl lactones J Chem Soc Perkin Trans 1 1999 2 103 105 doi 10 1039 A808436JExternal links edithttps www organic chemistry org Highlights 2004 22November shtm Retrieved from https en wikipedia org w index php title Julia Colonna epoxidation amp oldid 1006781510, wikipedia, wiki, book, books, library,

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