Abstract
Amino acids are essential to all life. However, our understanding of some aspects of their intrinsic structure, molecular chemistry, and electronic structure is still limited. In particular the nature of amino acids in their crystalline form, often essential to biological and medical processes, faces a lack of knowledge both from experimental and theoretical approaches. An important experimental technique that has provided a multitude of crucial insights into the chemistry and electronic structure of materials is x-ray photoelectron spectroscopy. While the interpretation of spectra of simple bulk inorganic materials is often routine, interpreting core level spectra of complex molecular systems is complicated to impossible without the help of theory. We have previously demonstrated the ability of density functional theory to calculate binding energies of simple amino acids, using ΔSCF implemented in a systematic basis set for both gas phase (multiwavelets) and solid state (plane waves) calculations. In this study, we use the same approach to successfully predict and rationalise the experimental core level spectra of phenylalanine (Phe), tyrosine (Tyr), tryptophan (Trp), and histidine (His) and gain an in-depth understanding of their chemistry and electronic structure within the broader context of more than 20 related molecular systems. The insights gained from this study provide significant information on the nature of the aromatic amino acids and their conjugated side chains.
Highlights
Amino acids form the basis of peptides and proteins, which are fundamental building blocks of life, and they are of great scientific interest for a multitude of reasons, first and foremost due to their role in biology and related use in pharmacology and medicine
We have previously demonstrated the ability of density functional theory to calculate binding energies of simple amino acids, using ΔSCF implemented in a systematic basis set for both gas phase and solid state calculations
Calculated binding energy (BE) for the solid state amino acids are presented in table 1
Summary
Amino acids form the basis of peptides and proteins, which are fundamental building blocks of life, and they are of great scientific interest for a multitude of reasons, first and foremost due to their role in biology and related use in pharmacology and medicine. Their systematic nature makes them perfect test systems to understand important aspects of the behaviour of molecular systems, including local and long-range structure and interactions, polymorphism, the three-dimensional arrangement of proteins, and ionic behaviour and its tunability by the environment.
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