The polyalanine-based peptide series Ac-Ala_n-LysH+ (n=5-20) is a prime
example that a secondary structure motif which is well-known from the solution
phase (here: helices) can be formed in vacuo. We here revisit this conclusion
for n=5,10,15, using density-functional theory (van der Waals corrected
generalized gradient approximation), and gas-phase infrared vibrational
spectroscopy. For the longer molecules (n=10,15) \alpha-helical models provide
good qualitative agreement (theory vs. experiment) already in the harmonic
approximation. For n=5, the lowest energy conformer is not a simple helix, but
competes closely with \alpha-helical motifs at 300K. Close agreement between
infrared spectra from experiment and ab initio molecular dynamics (including
anharmonic effects) supports our findings.Comment: 4 pages, 4 figures, Submitted to JPC Letter

Beachy M. D.

Benesch J.

Blum V.

Borysow J.

Cimas A.

Dion M.

Frauke Bierau

Gaigeot M.-P.

Gerard Meijer

Gert von Helden

Grimme S.

Havu V.

Hove M. V.

Hudgins R. R.

Jurecka P.

Kaminski G. A.

Kevin Pagel

Kohtani M.

Lee K.

Li X.

Mariana Rossi

Matthias Scheffler

Mortenson P.

Oboodi M. R.

Oepts D.

Oomens J.

Pendry J.

Penev E.

Perdew J. P.

Peter Kupser

Price M.

Ramirez R.

Stearns J. A.

Tkatchenko A.

Vaden T. D.

Valle J.

Volker Blum

Weymuth T.

Wu Q.

Wyttenbach T.

English

arXiv

The polyalanine-based peptide series Ac-Alan-LysH+ (n = 5−20) is a prime example that a secondary structure motif that is well-known from the solution phase (here: helices) can be formed in vacuo. Here we revisit the series members n = 5,10,15, using density functional theory (van der Waals corrected generalized gradient approximation) for structure predictions, which are then corroborated by room temperature gas-phase infrared vibrational spectroscopy. We employ a quantitative comparison based on Pendry’s reliability factor (popular in surface crystallography). In particular, including anharmonic effects into calculated spectra by way of ab initio molecular dynamics produces remarkably good experiment−theory agreement. We find the longer molecules (n = 10,15) to be firmly α-helical in character. For n = 5, calculated free-energy differences show different H-bond networks to still compete closely. Vibrational spectroscopy indicates a predominance of α-helical motifs at 300 K, but the lowest-energy conformer is not a simple helix

Rossi, M.

Blum, V.

Kupser, P.

Helden, G.

Bierau, F.

Pagel, K.

Meijer, G.

Scheffler, M.

MPG.PuRe