Exploring New Horizons in Microwave-Promoted Iminyl Radical Chemistry and Synthesis of Bulky Dehydroamino Acids

Singh, Jatinder

14 August 2023

The first project in this dissertation presents a simplified and efficient protocol for synthesizing pyrrolines through 5-exo iminyl radical cyclizations. The microwave irradiation of O-Phenyloximes tethered to alkenes causes N-O homolysis resulting in iminyl radical generation, which subsequently undergoes 5-exo-trig cyclizations furnishing pyrrolines. This eliminates the need for toxic radical initiators (AIBN, benzoyl peroxide), propagating agents (Bu3SnH, (Me3Si)3SiH), and expensive catalysts or single-electron transfer (SET) cycles. We explored the scope of diverse traps and substrates for iminyl radical cyclizations. The iminyl radical cyclizations formed versatile pyrrolines with moderate to excellent yields. The diastereoselectivity also ranged from low to high. Moreover, these versatile pyrrolines were further transformed via various reactions, such as hydrogenation, allylation, dihydroxylation, and cross-metathesis. The second part of this project extends the scope of the non-redox iminyl-radical based approach to γ-C(sp3)−H ketone activation. The sequence of N-O homolysis triggered by microwave irradiation of O-phenyloximes, 1,5-hydrogen atom transfer (HAT), trapping of the radical intermediate, and in situ imine hydrolysis, ultimately leads to the formal γ-C–H functionalization of ketones. We achieved both C-O and C-C bond formation by using diverse O-phenyloxime substrates. This work's notable achievement was accomplishing γ-C–H activation of 1o carbon atoms, a feat that has not been attained using SET-based iminyl radical chemistry. The third part of this dissertation focuses on the influence that dehydroamino acids have on secondary structures. This project describes the synthesis of incipient 310 helical tetrapeptides containing dehydroamino acids. A bulky dehydroethylnorvaline-containing tetrapeptide was synthesized. Based on our published data, we speculated that dehydroethylnorvaline might increase peptide proteolytic stability.

Iminyl radicals

Pyrrolines

Microwave irradiation

C-H activation

1

5-Hydrogen atom transfer (HAT)

bulky dehydroamino acids

Physical Sciences and Mathematics

Synthesis and Applications of α,β-Dehydroamino Acid-Containing Peptides

Moya, Diego A.

13 June 2022

Yaku’amide A (YA) is a linear anticancer peptide that is rich in bulky dehydroamino acids (ΔAAs) and β-hydroxyamino acids (β-OHAAs). In our recent total synthesis of YA, we featured a one-pot anti dehydration–azide reduction–O→N acyl transfer process for the stereospecific construction of Z- and E- ∆Ile residues. Despite previous total syntheses and our efforts, the synthesis of YA remains lengthy. Via computational studies, we identified two analogue peptides that closely resemble the conformation of YA. The use of simpler and symmetrical bulky ΔAAs such as dehydrovaline (ΔVal) and dehydroethylnorvaline (ΔEnv) as surrogates of ∆Ile, along with azlactone chemistry for their incorporation, significantly decreased the overall number of synthetic steps. Biological studies revealed that our analogues exhibited very similar activity to that of the natural product YA, demonstrating their suitability as mimics and consistency with our computational model. Despite its utility in the construction of YA analogues, azlactone chemistry is sluggish and moderate to low yielding. For this reason, we have explored strategies to streamline the synthesis of peptides containing Z-dehydroaminobutyric acid (∆Abu), ∆Val, and Z-dehydrophenylalanine (∆Phe). The key process is to form the alkene moiety via elimination of a β-sulfonium or β-OHAA embedded within a peptide, avoiding the need to form the alkene moiety via azlactone-dipeptide dehydration and bypassing sluggish amidation/ring opening steps. β-sheet disruption of Tau-model hexapeptides is a key type of inhibition for modulating Alzheimer’s disease progression. Previous studies replaced key residues with proline, due to its rigidity and lack of amide proton, to inhibit β-sheet formation. Similar to proline, ∆AAs are also known for their rigidity and ability to favor other conformations (e.g. β-hairpin, 310-helix) along with increasing peptide half-life. We have incorporated ∆Abu, ∆Val and dehydrocyclohexylglycine (∆Chg) in a highly aggregative hexapeptide sequence, using previously studied methods, to assess their capabilities as putative β-sheet breakers and to stabilize against proteolysis. Studies are continuing.

peptides

synthesis

dehydrations

bulky dehydroamino acids

azlactones

anticancer

computational studies

inhibitory effects

β-sulfonium

β-hydroxyamino acid

β-sheets

Alzheimer’s disease

proteolysi

Physical Sciences and Mathematics