2017
DOI: 10.1021/acs.orglett.7b01172
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Hydrophobic α,α-Disubstituted Disilylated TESDpg Induces Incipient 310-Helix in Short Tripeptide Sequence

Abstract: To evaluate the contribution of triethylsilyl α,α-di-n-propylglycine, namely TESDpg, to induce a defined secondary structure, we have prepared model tripeptides in which TESDpg was inserted in three different positions. Studies in solid state and in solution with adapted techniques showed that TESDpg was able to induce a nascent 3 helix in both crystal and solution states.

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Cited by 12 publications
(7 citation statements)
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“…Particularly promising are silicon-containing amino acids, 4 which may additionally stabilize certain secondary structures. 5 In our opinion, the most interesting case reported to date is the "lipophilic polyproline-II structure" constructed by Martin et al 6 In particular, NMR investigations of an oligomeric sis, prior to the α-helix and much earlier than the hydrophobic motif was recruited by nature. 19 This follows the GC-GCA-GCAU scheme of the genetic code evolution as recently summarized by Hartman and Smith.…”
Section: Hydrophobic Peptidesmentioning
confidence: 99%
See 1 more Smart Citation
“…Particularly promising are silicon-containing amino acids, 4 which may additionally stabilize certain secondary structures. 5 In our opinion, the most interesting case reported to date is the "lipophilic polyproline-II structure" constructed by Martin et al 6 In particular, NMR investigations of an oligomeric sis, prior to the α-helix and much earlier than the hydrophobic motif was recruited by nature. 19 This follows the GC-GCA-GCAU scheme of the genetic code evolution as recently summarized by Hartman and Smith.…”
Section: Hydrophobic Peptidesmentioning
confidence: 99%
“…A potential solution to these issues might be offered by the use of strongly lipophilic and bulkier side chains. Particularly promising are silicon‐containing amino acids, which may additionally stabilize certain secondary structures . In our opinion, the most interesting case reported to date is the “lipophilic polyproline‐II structure” constructed by Martin et al In particular, NMR investigations of an oligomeric proline analogue called silaproline (Sip, 1 , Figure ) revealed that the solution structure is dominated by the polyproline‐II (P II ) helix .…”
Section: Introductionmentioning
confidence: 98%
“…Another notable class of peptides is peptaibols, the structures with two substitutions at the α-carbon. The simplest structure in this set 2-aminoisobutiric acid, which favors the α-helix, whereas larger substituents can help stabilize other backbone conformations such as 3 10 -helix [45] or fully extended 2.0 5 -helix, an unusual structure not present in natural proteomes [46].…”
Section: The Alanine Worldmentioning
confidence: 99%
“…The insertion of unnatural amino acids (UAAs) in peptides and peptide mimics could add specific features to these molecules, such as proteolytic stability, active functional groups and new reactivity (Clerici et al, 2016; Pellegrino et al, 2016, 2017; Bucci et al, 2017). α,α disubstituted and β- homologs of natural amino acids have been particularly studied during the years for their ability to introduce conformational constrains in peptides and to stabilize specific secondary structures (Bonetti et al, 2015; Pellegrino et al, 2015; Fanelli et al, 2017; Kobayashi et al, 2017). On the other hand, γ UAAs provide a further opportunity to engineer the available backbone through the incorporation of an additional methylene group (Vasudev et al, 2011; Sohora et al, 2018).…”
Section: Introductionmentioning
confidence: 99%