Ester Carbonyl Vibration as a Sensitive Probe of Protein Local Electric Field

Pazos, Ileana M.; Ghosh, Ayanjeet; Tucker, Matthew J.; Gai, Feng

doi:10.1002/ange.201402011

Cited by 32 publications

(62 citation statements)

References 47 publications

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“…), comparison between the Fourier transform infrared (FTIR) spectra of YGGCGG and YGGC * GG obtained in D 2 O also validates the successful incorporation of the ME group. This is because the YGGC * GG peptide, but not the YGGCGG peptide, gives rise to an IR band within the region of 1700–1750 cm −1 . As expected, this ester carbonyl stretching vibrational band is broad and peaked at about 1720 cm −1 , which is similar to that observed for a short peptide containing a D M residue, due to hydrogen‐bonding interactions with the solvent molecules …”

Section: Resultssupporting

confidence: 77%

“…Recently, Pazos et al have shown that the ester carbonyl stretching vibration is a useful and convenient site‐specific IR probe of protein electrostatics because (1) its frequency is linearly correlated with the local electrostatic field, even when the carbonyl group is engaged in hydrogen‐bonding interactions; (2) its frequency is located in the spectral range of 1700–1800 cm −1 , wherein no intrinsic protein vibrations show up at neutral pH; and (3) it has a relatively high extension coefficient. In particular, Pazos et al have tested and demonstrated the utility of two ester‐containing non‐natural amino acids, l ‐aspartic acid 4‐methyl ester (hereafter referred to as D M ) and l ‐glutamic acid 5‐methyl ester (hereafter referred to as E M ), by incorporating them into various model peptide systems via solid‐phase peptide synthesis. In contrast, other non‐natural amino acid‐based IR probes, such as p ‐cyanophenylalanine and p ‐azido‐phenylalanine, have been incorporated into large proteins in vivo via amber codon suppression .…”

Section: Introductionmentioning

confidence: 99%

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Simple method to introduce an ester infrared probe into proteins

Ahmed

Gai

2017

Protein Science

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The ester carbonyl stretching vibration has recently been shown to be a sensitive and convenient infrared (IR) probe of protein electrostatics due to the linear dependence of its frequency on local electric field. While an ester moiety can be easily incorporated into peptides via solid-phase synthesis, currently there is no method available to site-specifically incorporate it into a large protein. Herein, we show that it is possible to use a cysteine alkylation reaction to achieve this goal and demonstrate the feasibility of this simple method by successfully incorporating a methyl ester group (CH COOCH ) into a model peptide (YGGCGG), two amyloid-forming peptides derived from the insulin B chain and Aβ, and bovine serum albumin (BSA). IR results obtained with those peptide and protein systems further confirm the utility of this vibrational probe in monitoring, for example, the structural integrity of amyloid fibrils and ligand binding-induced changes in protein local hydration status.

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Section: Resultssupporting

confidence: 77%

Section: Introductionmentioning

confidence: 99%

Simple method to introduce an ester infrared probe into proteins

Ahmed

Gai

2017

Protein Science

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“…In a second example, Pazos et al (126) further showed that the C=O stretching frequency of two esters (i.e., methyl propionate and methyl acetate) afford similar spectroscopic properties as that of acetophenone. However, because the C=O stretching vibration of esters is typically in the range of 1710–1750 cm −1 , which decreases its spectral overlap with the amide I band of proteins, it offers certain advantages.…”

Section: Sidechain-based Ir Probesmentioning

confidence: 99%

Site-Specific Infrared Probes of Proteins

Pazos²,

Zhang³

et al. 2015

Annu. Rev. Phys. Chem.

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161

189

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Infrared spectroscopy has played an instrumental role in studying a wide variety of biological questions. However, in many cases it is impossible or difficult to rely on the intrinsic vibrational modes of biological molecules of interest, such as proteins, to reveal structural and/or environmental information in a site-specific manner. To overcome this limitation, many recent efforts have been dedicated to the development and application of various extrinsic vibrational probes that can be incorporated into biological molecules and used to site-specifically interrogate their structural and/or environmental properties. In this Review, we highlight some recent advancements of this rapidly growing research area.

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“…Furthermore, vibrational solvatochromism can be used to systematically vary the field experienced by the probe in fluid solution, and the resulting spectral shifts can be related to the absolute electric field through MD simulations. 3–5 The separately measured Stark tuning rate (by VSS) provides a bridge between these two approaches. Additional computational methods have also been developed to determine the environmental effects on vibrational frequencies.…”

Section: Introductionmentioning

confidence: 99%

“…16–19 The carbonyl (C=O) vibration, which is generally more intense than nitriles, has been shown to vary linearly with electrostatic field in both H-bonding and non-H-bonding environments. 3, 5, 7–8, 20 The main limitation of the carbonyl probe is that its frequency overlaps with the densely populated amide I region in many biological systems. Fortunately, this can often be overcome by careful selection of a reference sample that is nearly identical to the sample of interest as well as isotopic labeling, or by using Raman spectroscopy.…”

Section: Introductionmentioning

confidence: 99%

Vibrational Stark Effects of Carbonyl Probes Applied to Reinterpret IR and Raman Data for Enzyme Inhibitors in Terms of Electric Fields at the Active Site

2016

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IR and Raman frequency shifts have been reported for numerous probes of enzyme transition states, leading to diverse interpretations. In the case of the model enzyme ketosteroid isomerase (KSI), we have argued that IR spectral shifts for a carbonyl probe at the active site can provide a connection between the active site electric field and the activation free energy (Fried et al. Science, 2014, 346, 1510–1514). Here we generalize this approach to a much broader set of carbonyl probes (e.g. oxoesters, thioesters, and amides), first establishing the sensitivity of each probe to an electric field using vibrational Stark spectroscopy, vibrational solvatochromism, and MD simulations, and then applying these results to re-interpret data already in the literature for enzymes such as 4-chlorobenzoyl-CoA dehalogenase and serine proteases. These results demonstrate that the vibrational Stark effect provides a general framework for estimating the electrostatic contribution to the catalytic rate and may provide a metric for the design or modification of enzymes. Opportunities and limitations of the approach are also described.

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Ester Carbonyl Vibration as a Sensitive Probe of Protein Local Electric Field

Cited by 32 publications

References 47 publications

Simple method to introduce an ester infrared probe into proteins

Simple method to introduce an ester infrared probe into proteins

Site-Specific Infrared Probes of Proteins

Vibrational Stark Effects of Carbonyl Probes Applied to Reinterpret IR and Raman Data for Enzyme Inhibitors in Terms of Electric Fields at the Active Site

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