Mid-IRspectra of different conformers of phenylalanine in the gas phase

Helden, Gert von; Compagnon, Isabelle; Blom, Martine N.; Frankowski, Marcin; Erlekam, Undine; Brauer, Brina; Gerber, R. Benny; Meijer, Gerard

doi:10.1039/b713274c

Cited by 53 publications

(59 citation statements)

References 35 publications

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“…As the number of water molecules is increased, the bridge becomes longer. [9] Meijer and coworkers [10] reported mid-and far-IR spectra of six conformers of phenylalanine in the gas phase and they have found good agreement between experiment and theoretical spectra. The conformational behavior and IR spectrum of L-phenylalanine by matrix-isolation IR spectroscopy and DFT calculations showed that the 14 most stable structures which differ in energy by less than 10 kJ mol À1 , and the entropy also plays an essential role in determining the relative abundance of the possible low-energy conformational states in phenylalanine.…”

Section: Introductionmentioning

confidence: 69%

A computational investigation and the conformational analysis of dimers, anions, cations, and zwitterions ofL‐phenylalanine

2011

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The structure and stability of various conformations of L-phenylalanine (PheN) and its zwitterions (PheZ), along with their ionized counterparts, cation (PheC) and anion (PheA), generated by adding and removing a proton respectively, have been investigated using first principle calculations in vacuum and in solution. This is followed by an extensive study on various possible dimer (PheD) conformations, which are noncovalently bound units without a peptide bond. This study results in 52, 31, 12, 9, and 11 minimum energy structures on the potential energy surfaces of PheD, PheN, PheC, PheA, and PheZ, respectively. Several important nonbonded interactions such as hydrogen bonds, NH-π, CH-π, OH-π, and π-π interactions, which impart stability to the monomeric and dimeric units, have been analyzed. The capability and strength of the nonbonded interactions drastically changing the conformational orientations of monomeric units has been illustrated.

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Section: Introductionmentioning

confidence: 69%

A computational investigation and the conformational analysis of dimers, anions, cations, and zwitterions ofL‐phenylalanine

2011

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“…The low intensity of the observed spectra and the non-observation of the conformers, detected with other techniques, can be caused by ionization and photofragmentation processes during laser ablation taking place with different rates for the different conformers. Kim and co-workers [145][146][147], from their measurements of the ionization energies (IE) of the low-energy conformers of phenylalanine, affirm that the observed conformers IIa and IIb have higher IEs than the other conformers.…”

Section: Phenylglycine and Phenylalaninementioning

confidence: 76%

Microwave Spectroscopy of Biomolecular Building Blocks

Alonso

López

2014

Topics in Current Chemistry

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Microwave spectroscopy, considered as the most definitive gas phase structural probe, is able to distinguish between different conformational structures of a molecule, because they have unique spectroscopic constants and give rise to distinct individual rotational spectra.Previously, application of this technique was limited to molecular specimens possessing appreciable vapor pressures, thus discarding the possibility of studying many other molecules of biological importance, in particular those with high melting points, which had a tendency to undergo thermal reactions, and ultimately degradation, upon heating.Nowadays, the combination of laser ablation with Fourier transform microwave spectroscopy techniques, in supersonic jets, has enabled the gas-phase study of such systems. In this chapter, these techniques, including broadband spectroscopy, as well as results of their application into the study of the conformational panorama and structure of biomolecular building blocks, such as amino acids, nucleic bases, and monosaccharides, are briefly discussed, and with them, the tools for conformational assignation - rotational constants, nuclear quadrupole coupling interaction, and dipole moment.

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“…3.3). Vibrational couplings make the interpretation less easy, and confident assignments rely on a large spectral range (the whole amide I-III regions), especially when spectral resolution is limited, usually 1% of the IR frequency for a freeelectron source [48,54,55,66,69,79,80,82,83,95,97,105,108,131,132,136,141,142]. Difference frequency generation from table-top OPOs [52,64,90,104,120,126,127,137,139,144,145] has become a valuable alternative source to FELs, providing spectral resolutions in the cm À1 range, and solid conformational assignments have emerged from studies combining amide I/II and amide A spectral ranges (Fig.…”

Section: Methodsmentioning

confidence: 99%

Isolated Neutral Peptides

Gloaguen

Mons

2014

Topics in Current Chemistry

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This chapter examines the structural characterisation of isolated neutral amino-acids and peptides. After a presentation of the experimental and theoretical state-of-the-art in the field, a review of the major structures and shaping interactions is presented. Special focus is made on conformationally-resolved studies which enable one to go beyond simple structural characterisation; probing flexibility and excited-state photophysics are given as examples of promising future directions.

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Mid-IRspectra of different conformers of phenylalanine in the gas phase

Cited by 53 publications

References 35 publications

A computational investigation and the conformational analysis of dimers, anions, cations, and zwitterions ofL‐phenylalanine

A computational investigation and the conformational analysis of dimers, anions, cations, and zwitterions ofL‐phenylalanine

Microwave Spectroscopy of Biomolecular Building Blocks

Isolated Neutral Peptides

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