Hydrogen Tunneling above Room Temperature Evidenced by Infrared Ion Spectroscopy

Schäfer, Matthias; Peckelsen, Katrin; Paul, Mathias; Martens, Jonathan; Berden, Giel; Berkessel, Albrecht; Meijer, Anthony J. H. M.

doi:10.1021/jacs.6b10348

Cited by 32 publications

(90 citation statements)

References 54 publications

Supporting

Mentioning

Contrasting

Order By: Relevance

“…The cc-pVTZ basis set was used throughout with the ultrafine setting for the integrals [29,30]. This computational procedure was found to give good correlation with experiment in previous work [31]. All the calculations performed on these systems were done in vacuo.…”

Section: Theorymentioning

confidence: 99%

Gas-phase complexes of Ni2+ and Ca2+ with deprotonated histidylhistidine (HisHis): A model case for polyhistidyl-metal binding motifs

Peckelsen

Martens

Berden

et al. 2017

Journal of Molecular Spectroscopy

Self Cite

View full text Add to dashboard Cite

In the complex formed between the calcium cation (Ca 2+) and a deprotonated HisHis dipeptide, the complex adopts a charge solvation (CS) structure. Ca 2+ , a weak binding main group metal cation, interacts with the oxygens of the peptide carbonyl moiety and the deprotonated C-In contrast, the much stronger binding Ni 2+ cation deprotonates the peptide nitrogen and induces an iminolate (Im) ligand structure in the [Ni(HisHis-H)] + complex ion. The combination of infrared multiple-photon dissociation (IRMPD) spectroscopy and quantum chemistry evidence these two representative binding motifs. The iminolate coordination pattern identified and characterized in the [Ni(HisHis-H)] + complex serves as a model case for nickel complexes of poly-histidyl-domains and is thereby also of interest to better understand the fundamentals of immobilized metal ion affinity chromatography as well as of Ni co-factor chemistry in enzymology.

show abstract

Section: Theorymentioning

confidence: 99%

Gas-phase complexes of Ni2+ and Ca2+ with deprotonated histidylhistidine (HisHis): A model case for polyhistidyl-metal binding motifs

Peckelsen

Martens

Berden

et al. 2017

Journal of Molecular Spectroscopy

Self Cite

View full text Add to dashboard Cite

show abstract

“…IR-IS has evolved in little more than a decade from an experimental technique in academic labs studying fundamental molecular physics (Lemaire et al 2002 ; Aleese et al 2006 ; Oomens et al 2006 ; Fridgen 2009 ; Polfer and Oomens 2009 ) to its current state, in which it is a demonstrated (bio)analytical technique for the identification of small molecules in complex mixtures (Martens et al 2017a , b ), though still limited to user facilities or state-of-the-art laboratories housing the most advanced tuneable infrared laser technology. In the past decade, IR-IS has been used to identify and characterize the molecular structures of many classes of chemical compounds including amino acids (Polfer et al 2005 , 2006a ; Correia et al 2008 ; Rodgers et al 2008 ; Oomens and Steill 2009 ; Scuderi et al 2011 ), nucleotides and bases (Salpin et al 2007 ; Chiavarino et al 2013 ), peptides and proteins (Balaj et al 2008 ; Polfer et al 2008 ; Yoon et al 2008 ; Fukui and Takahashi 2012 ; Martens et al 2012 , 2015 , 2016a ; Stedwell et al 2012 ; Scuderi et al 2015 ; Dunbar et al 2017 ), saccharides (Martens et al 2017b ; Polfer et al 2006b ; Cagmat et al 2010 ; Contreras et al 2012 ; Schindler et al 2014 , 2017 ), neurotransmitters (Lagutschenkov et al 2010 , 2011 ), and a variety of other mainly small organic compounds and reaction products (Martens et al 2017a ; MacAleese and Maître 2007 ; Rummel et al 2011 ; De Petris et al 2013 , 2016b ; Warnke et al 2015 ; Cismesia et al 2016 ; Seo et al 2016 ; Schäfer et al 2017 ; Gorlova et al 2017 ). Here we outline various ways IR-IS can currently be utilized by the metabolomics community.…”

Section: Introductionmentioning

confidence: 99%

Unraveling the unknown areas of the human metabolome: the role of infrared ion spectroscopy

Martens

Berden

Bentlage

et al. 2018

J of Inher Metab Disea

Self Cite

View full text Add to dashboard Cite

The identification of molecular biomarkers is critical for diagnosing and treating patients and for establishing a fundamental understanding of the pathophysiology and underlying biochemistry of inborn errors of metabolism. Currently, liquid chromatography/high-resolution mass spectrometry and nuclear magnetic resonance spectroscopy are the principle methods used for biomarker research and for structural elucidation of small molecules in patient body fluids. While both are powerful techniques, several limitations exist that often make the identification of unknown compounds challenging. Here, we describe how infrared ion spectroscopy has the potential to be a valuable orthogonal technique that provides highly-specific molecular structure information while maintaining ultra-high sensitivity. Here, we characterize and distinguish two well-known biomarkers of inborn errors of metabolism, glutaric acid for glutaric aciduria and ethylmalonic acid for short-chain acyl-CoA dehydrogenase deficiency, using infrared ion spectroscopy. In contrast to tandem mass spectra, in which ion fragments can hardly be predicted, we show that the prediction of an IR spectrum allows reference-free identification in the case that standard compounds are either commercially or synthetically unavailable. Finally, we illustrate how functional group information can be obtained from an IR spectrum for an unknown and how this is valuable information to, for example, narrow down a list of candidate structures resulting from a database query. Early diagnosis in inborn errors of metabolism is crucial for enabling treatment and depends on the identification of biomarkers specific for the disorder. Infrared ion spectroscopy has the potential to play a pivotal role in the identification of challenging biomarkers.

show abstract

“…Recent experimental findings imply that selectivity based on thermodynamic versus kinetic control is undermined by quantum mechanical tunneling (QMT) that can override this classic concept. The concept of a product that forms despite a high barrier that cannot be overcome (within finite time) at a given (low) temperature was termed “tunneling control,” and can be considered as the third paradigm of chemical reactivity next to kinetic and thermodynamic control .…”

Section: Introductionmentioning

confidence: 99%

TUNNEX: An easy‐to‐use wentzel‐kramers‐brillouin (WKB) implementation to compute tunneling half‐lives

Quanz

Schreiner

2018

J Comput Chem

View full text Add to dashboard Cite

Tunneling in experiments (TUNNEX) is a free open-source program with an easy-to-use graphical user interface to simplify the process of Wentzel-Kramers-Brillouin (WKB) computations. TUNNEX aims at experimental chemists with basic knowledge of computational chemistry, and it offers the computation of tunneling half-lives, visualization of data, and exporting of graphs. It also provides a helper tool for executing the zeropoint vibrational energy correction along the path. The program also enables computing high-level single points along the intrinsic reaction path. TUNNEX is available at https://github. com/prs-group/TUNNEX. As the WKB approximation usually overestimates tunneling half-lives, it can be used to screen tunneling processes before proceeding with elaborate kinetic experiments or higher-level tunneling computations such as instanton theory and small curvature tunneling approaches.

show abstract

Hydrogen Tunneling above Room Temperature Evidenced by Infrared Ion Spectroscopy

Cited by 32 publications

References 54 publications

Gas-phase complexes of Ni2+ and Ca2+ with deprotonated histidylhistidine (HisHis): A model case for polyhistidyl-metal binding motifs

Gas-phase complexes of Ni2+ and Ca2+ with deprotonated histidylhistidine (HisHis): A model case for polyhistidyl-metal binding motifs

Unraveling the unknown areas of the human metabolome: the role of infrared ion spectroscopy

TUNNEX: An easy‐to‐use wentzel‐kramers‐brillouin (WKB) implementation to compute tunneling half‐lives

Contact Info

Product

Resources

About