Analysis of the Cryptophycin P450 Epoxidase Reveals Substrate Tolerance and Cooperativity

Ding, Yousong; Seufert, Wolfgang; Beck, Zachary Q.; Sherman, David H.

doi:10.1021/ja710520q

Cited by 38 publications

(35 citation statements)

References 66 publications

Supporting

Mentioning

Contrasting

Order By: Relevance

“…[17] Perhaps of great significance, however, is the observation that peptidomimetic catalyst 9 exhibits conformational properties that are surprisingly different from catalyst 5. Whereas catalyst 5 appears as a single conformation in solution by 1 H NMR (400 MHz) (Figure 1 a), consistent with the b-turn observed in the X-ray structure of 8, catalyst 9 appears as a heterogeneous 3.5:1 mixture of two distinct catalyst conformations (Figure 1 b). Notably, the signals coalesce when the NMR sample is heated to 100 8C ([D 6 ]DMSO solvent).…”

supporting

confidence: 74%

See 1 more Smart Citation

Functional Analysis of an Aspartate‐Based Epoxidation Catalyst with Amide‐to‐Alkene Peptidomimetic Catalyst Analogues

2008

View full text Add to dashboard Cite

Keywordsepoxidation; peptide; asymmetric catalysis; olefin isostere; fluorine; peptidomimetic The biosynthesis of natural products that contain epoxides represents a powerful stimulus for the study of "epoxidase" enzymes. [i] Likewise, these processes have inspired a generation of science focused on small molecule catalysts that mediate selective epoxidations through a variety of mechanisms. [ii] With respect to the naturally occurring epoxidases, the mechanistic basis of O-atom transfer is often associated with the chemistry of either flavinoid cofactors, P450 enzymes containing a heme group, or chloroperoxidases that lead to stepwise ring formation. [iii] In thinking about the known biosynthetic apparatus for epoxide formation, we became curious about an alternative mode for O-atom transferone based on functional groups available in proteins, but perhaps not well-documented in the biosynthesis of epoxides. In particular, we speculated and recently showed that asparticacid-containing peptides (e.g., 1; Figure 1a) might shuttle between the side-chain carboxylic acid and the corresponding peracid (e.g., 2) creating a catalytic cycle competent for asymmetric epoxidation with turnover of the aspartate-derived catalyst. Such an approach is orthogonal to the Julia-Colonna epoxidation, a complementary peptide-based epoxidation based on a nucleophilic mechanism. [iv] Indeed, as shown in Figure 1b, this new electrophilic epoxidation catalytic cycle mediates the asymmetric epoxidation of substrates like 3 to give products like 4 with up to 92% ee. [v] Mechanistic questions abound in this catalytic system. To date, we have identified a number of relevant aspects. For example, we observed off-catalytic cycle intermediates, including catalytically inactive diacyl peroxides (6). [vi] We also showed that these off-cycle intermediates could be reinserted into the productive pathway through the action of nucleophiles such as DMAP or DMAP-N-oxide (7). On the other hand, the basis of stereochemical information transfer was not immediately clear. Indeed, the high precision delineation of the stereochemical mode of action of chiral catalysts is a critical frontier in the discipline of asymmetric catalysis, whether the catalysts are enzymes or small molecules. With this back-drop, we began a detailed study of the mode of action for catalyst 5.The conversion of 3 to 4 was originally undertaken with the hypothesis that substratecatalyst hydrogen bonding might contribute to transition state organization. [vii] Indeed, a substrate lacking obvious H-bonding capability (phenylcyclohexene) was found to undergo epoxidation with catalyst 5 with low enantioselectivity (~10% ee). Thus, we envisioned several potential loci for contacts between 3 and 5 (Figure 2a). Shown in blue is the site that

show abstract

supporting

confidence: 74%

“…Whereas the 1 H NMR spectra for catalyst 9 reveal a 3.5:1 conformational mixture (23 8C), fluoroalkene catalyst 11 exhibits an approximately 10:1 mixture of conformations at the same temperature (Figure 1 c). Once again, coalescence of the spectrum is observed when the sample is examined by 1 …”

mentioning

confidence: 99%

Functional Analysis of an Aspartate‐Based Epoxidation Catalyst with Amide‐to‐Alkene Peptidomimetic Catalyst Analogues

2008

View full text Add to dashboard Cite

show abstract

“…The same research group also reported that the thioesterase portion of the crpD synthase could be expressed in a heterologous host, purified, and then reacted in vitro to produce cryptophycin analogs from synthetic, linear precursors [29]. This chemoenzymatic approach was further improved by the identification and purification of the cryptophycin P450 epoxidase, which allowed the chemoenzymatic formation of the benzylic epoxide from styrene-containing cryptophycin precursors [30]. Ultimately, the results from these synthetic and biosynthetic studies could be used to develop a second generation of cryptophycins with improved efficacy with lower toxicity than the first clinical candidate, cryptophycin 52.…”

Section: Cytotoxic Metabolites From Cyanobacteriamentioning

confidence: 99%

Chemodiversity in Freshwater and Terrestrial Cyanobacteria – A Source for Drug Discovery

Chlipala¹,

Mo²,

Orjala³

2011

CDT

114

View full text Add to dashboard Cite

Cyanobacteria are considered a promising source for new pharmaceutical lead compounds and a large number of chemically diverse and bioactive metabolites have been obtained from cyanobacteria over the last few decades. This review highlights the structural diversity of natural products from freshwater and terrestrial cyanobacteria. The review is divided into three areas: cytotoxic metabolites, protease inhibitors, and antimicrobial metabolites. The first section discusses the potent cytotoxins cryptophycin and tolytoxin. The second section covers protease inhibitors from freshwater and terrestrial cyanobacteria and is divided in five subsections according to structural class: aeruginosins, cyanopeptolins, microviridins, anabaenopeptins, and microginins. Structure activity relationships are discussed within each protease inhibitor class. The third section, antimicrobial metabolites from freshwater and terrestrial cyanobacteria, is divided by chemical class in three subsections: alkaloids, peptides and terpenoids. These examples emphasize the structural diversity and drug development potential of natural products from freshwater and terrestrial cyanobacteria.

show abstract

“…Cooperativity of cytochromes P450 has been documented in vivo (Tang & Stearns, 2001), in liver microsomes (Oda & Kharasch, 2001; Zhang et al, 2004; Di Marco et al, 2005; Niwa, Murayama, & Yamazaki, 2008a) and in reconstituted systems with purified and isolated individual enzymes, as reviewed in (Guengerich, 1999; Houston & Kenworthy, 2000; Guengerich, 2005; Houston & Galetin, 2005; Atkins, 2006; Tracy, 2006) (Hlavica & Lewis, 2001) (Davydov & Halpert, 2008). In addition to the textbook examples of cooperative cytochromes P450 such as CYP107, CYP3A4, and CYP2C9, cooperativity has also been reported for mammalian xenobiotic metabolizing enzymes CYP1A2 (Sohl et al, 2008), CYP2A6 (Harrelson, Atkins, & Nelson, 2008), CYP2B1 (Scott, He, & Halpert, 2002), CYP2B6, and CYP2E1 (Spatzenegger et al, 2003), for bacterial enzymes CYP102 (Gustafsson et al, 2004; van Vugt-Lussenburg et al, 2006), CYP130 (Ouellet, Podust, & Ortiz de Montellano, 2008), CYP158A2 (Zhao et al, 2005), P450 crpE (Ding et al, 2008), and even for chloroperoxidase (Torres & Aburto, 2005; Aburto, Correa-Basurto, & Torres, 2008). …”

Section: Introductionmentioning

confidence: 95%

Cooperative properties of cytochromes P450

Denisov

Frank

Sligar

2009

Pharmacology & Therapeutics

100

View full text Add to dashboard Cite

Cytochromes P450 form a large and important class of heme monooxygenases with a broad spectrum of substrates and corresponding functions, from steroid hormone biosynthesis to the metabolism of xenobiotics. Despite decades of study, the molecular mechanisms responsible for the complex non-Michaelis behavior observed with many members of this super-family during metabolism, often termed ‘cooperativity,’ remain to be fully elucidated. Although there is evidence that oligomerization may play an important role in defining the observed cooperativity, some monomeric cytochromes P450, particularly those involved in xenobiotic metabolism, also display this behavior due to their ability to simultaneously bind several substrate molecules. As a result, formation of distinct enzyme-substrate complexes with different stoichiometry and functional properties can give rise to homotropic and heterotropic cooperative behavior. This review aims to summarize the current understanding of cooperativity in cytochromes P450, with a focus on the nature of cooperative effects in monomeric enzymes.

show abstract

Analysis of the Cryptophycin P450 Epoxidase Reveals Substrate Tolerance and Cooperativity

Cited by 38 publications

References 66 publications

Functional Analysis of an Aspartate‐Based Epoxidation Catalyst with Amide‐to‐Alkene Peptidomimetic Catalyst Analogues

Functional Analysis of an Aspartate‐Based Epoxidation Catalyst with Amide‐to‐Alkene Peptidomimetic Catalyst Analogues

Chemodiversity in Freshwater and Terrestrial Cyanobacteria – A Source for Drug Discovery

Cooperative properties of cytochromes P450

Contact Info

Product

Resources

About