Utility of 5-Cyanotryptophan Fluorescence as a Sensitive Probe of Protein Hydration

Markiewicz, Beatrice N.; Mukherjee, Debopreeti; Troxler, Thomas; Gai, Feng

doi:10.1021/acs.jpcb.5b12233

Cited by 46 publications

(83 citation statements)

References 55 publications

(84 reference statements)

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“…Indeed, our CD results (SI Appendix, Figs. S16 and S17) show that although TPA + clusters can induce α-helix formation in an alanine-based peptide, as observed by Dempsey et al (24), they do not increase the α-helicity of a Trp3/Trp CN mutant of the antimicrobial peptide mastoparan-X that is known to form an amphipathic α-helix upon binding to the interfacial region of lipid micelles or membranes (30). These results suggest that unlike membrane-mimic micelles formed by surfactants, a single TPA + cluster is unable to provide a continuous water-hydrophobic interface large enough to host an entire α-helix.…”

Section: Resultsmentioning

confidence: 59%

“…To help better understand the results obtained with linear and nonlinear IR spectroscopic methods, we also performed fluorescence measurements. It has been shown that the fluorescence quantum yields of Phe CN and Trp CN are sensitive to interactions with water molecules (29,30), with a relation that hydration increases/decreases the fluorescence intensity of Phe CN / Trp CN . Thus, both unnatural amino acids can in principle be used as fluorescence probes to assess how Gdm + and TPA + affect the local hydration status of Phe CN and Trp CN in GF CN G and GW CN G. However, we only carried out fluorescence experiment on GW CN G because Cl − is known to significantly quench the fluorescence of Phe CN (29).…”

Section: Resultsmentioning

confidence: 99%

“…To achieve this goal, herein we use multiple spectroscopic methods and two unnatural amino acids, p-cyano-phenylalanine (Phe CN ) and 5-cyano-tryptophan (Trp CN ), to directly assess whether protein aromatic side chains can preferentially interact with Gdm + and TPA + ions. Both the C≡N stretching vibration (27,28) and fluorescence quantum yield (29,30) of Phe CN and Trp CN have been shown to be sensitive to their local environment. Thus, the premise of our study is that any specific ion-side chain Significance Ever since the discovery by Franz Hofmeister in 1888 that a series of salts (now commonly referred to as the Hofmeister series) can have different but consistent effects on the solubility and hence stability of proteins, many studies have been devoted to understanding how such effects are achieved.…”

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confidence: 99%

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Do guanidinium and tetrapropylammonium ions specifically interact with aromatic amino acid side chains?

Ding

Mukherjee

Chen

et al. 2017

Proc. Natl. Acad. Sci. U.S.A.

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Many ions are known to affect the activity, stability, and structural integrity of proteins. Although this effect can be generally attributed to ion-induced changes in forces that govern protein folding, delineating the underlying mechanism of action still remains challenging because it requires assessment of all relevant interactions, such as ion-protein, ion-water, and ion-ion interactions. Herein, we use two unnatural aromatic amino acids and several spectroscopic techniques to examine whether guanidinium chloride, one of the most commonly used protein denaturants, and tetrapropylammonium chloride can specifically interact with aromatic side chains. Our results show that tetrapropylammonium, but not guanidinium, can preferentially accumulate around aromatic residues and that tetrapropylammonium undergoes a transition at ∼1.3 M to form aggregates. We find that similar to ionic micelles, on one hand, such aggregates can disrupt native hydrophobic interactions, and on the other hand, they can promote α-helix formation in certain peptides.T he stability of a protein, or more precisely, the free energy difference between its folded and unfolded states, can be modulated by various solution properties. For example, addition of another solute to a protein solution can result in either a decrease or an increase in this protein's stability (1-3). The most noticeable example in this regard is the Hofmeister series (4-6), a group of ions that are ranked based on their protein-denaturing abilities. Among this series, the guanidinium ion (Gdm + ) is the most widely used chemical agent in protein denaturation due to its strong destabilizing effect and high solubility in water. Consequently, its mechanism of action has been subjected to extensive studies (7)(8)(9)(10)(11)(12)(13)(14). Although different interpretations have been put forth (15-17), the generally accepted notion is that Gdm + denatures a protein by preferentially interacting with its peptide groups (7,11,18), including certain side chains (11,(19)(20)(21)(22). In particular, it has been hypothesized that Gdm + , which exists in aqueous solution as a rigid, flat object (12,18,19), can engage in stacking interactions with amino acids consisting of planar side chains, such as arginine (Arg) (19), asparagine (Asn) (11,20), glutamine (Gln) (11,20), and aromatic residues (20)(21)(22). However, to the best of our knowledge, the only experimental evidence that supports this hypothesis comes from crystallographic data (20)(21)(22), which show that the guanidinium group of Arg is more frequently found to be stacked against the side chain of tyrosine (Tyr) or tryptophan (Trp) in proteins. Therefore, additional experimental studies that can directly probe such stack interactions in solution are needed.Another ion in the Hofmeister series that has a similar proteindenaturing capability to Gdm + is tetrapropylammonium (TPA + ) (23). However, a recent study by Dempsey et al. (24) found that although TPA + , like Gdm + , can denature a tryptophan (Trp) zipper β-hairpin (i.e....

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Section: Resultsmentioning

confidence: 59%

Section: Resultsmentioning

confidence: 99%

mentioning

confidence: 99%

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Do guanidinium and tetrapropylammonium ions specifically interact with aromatic amino acid side chains?

Ding

Mukherjee

Chen

et al. 2017

Proc. Natl. Acad. Sci. U.S.A.

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“…This is consistent with previous neutron diffraction measurements on indole/methanol/water solutions, 9 as well as with infra-red measurements on indole derivatives in solution which have been shown to be sensitive to -OH bonding to the benzene ring motifs. 31,32 From the excess entropy calculations here, this appears to be enthalpically driven rather than entropically driven given that methanol is more ordered compared with water around indole in solution and indole has a much higher solubility in methanol compared with water.…”

Section: Discussionmentioning

confidence: 85%

On the positional and orientational order of water and methanol around indole: a study on the microscopic origin of solubility

Henao

Johnston

Guàrdia

et al. 2016

Phys. Chem. Chem. Phys.

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Although they are both highly polar liquids, there are a number of compounds, such as many pharmaceuticals, which show vastly different solubilities in methanol compared with water. From theories of the hydrophobic effect, it might be predicted that this enhanced solubility is due to association between drugs and the less polar -CH 3 groups on methanol. In this work, detailed analysis on the atomic structural interactions between water, methanol and the small molecule indole -which is a precursor to many drugs and is sparingly soluble in water yet highly soluble in methanol -reveal that indole preferentially interacts with both water and methanol via electrostatic interactions rather than with direction interactions to the -CH 3 groups. The presence of methanol hydrogen bonds with π electrons of the benzene ring of indole can explain the increase in solubility of indole in methanol relative to water. In addition, the excess entropy calculations performed here suggest that this solvation is enthalpically rather than entropically driven.

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“…Many past studies have focused on Trp-based unnatural amino acids, including azatryptophans (5,6,12) and various indole-ring substituted analogs (13)(14)(15)(16), aiming to identify useful biological fluorophores. Whereas some Trp analogs indeed exhibit improved fluorescent properties over Trp, none of them has found broad applications due to certain photophysical limitations.…”

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confidence: 99%

Blue fluorescent amino acid for biological spectroscopy and microscopy

Hilaire

Ahmed

Lin

et al. 2017

Proc. Natl. Acad. Sci. U.S.A.

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Many fluorescent proteins are currently available for biological spectroscopy and imaging measurements, allowing a wide range of biochemical and biophysical processes and interactions to be studied at various length scales. However, in applications where a small fluorescence reporter is required or desirable, the choice of fluorophores is rather limited. As such, continued effort has been devoted to the development of amino acid-based fluorophores that do not require a specific environment and additional time to mature and have a large fluorescence quantum yield, long fluorescence lifetime, good photostability, and an emission spectrum in the visible region. Herein, we show that a tryptophan analog, 4-cyanotryptophan, which differs from tryptophan by only two atoms, is the smallest fluorescent amino acid that meets these requirements and has great potential to enable in vitro and in vivo spectroscopic and microscopic measurements of proteins.fluorescence protein | fluorescence probe | unnatural amino acid | imaging O f the amino acids that are inherently responsible for the fluorescence of proteins, tyrosine (Tyr), tryptophan (Trp), and phenylalanine (Phe), Trp is the most widely used fluorescence reporter of protein structure, function, and dynamics, as its fluorescence quantum yield (QY) is comparatively large and is also sensitive to environment (1-3). However, Trp absorbs/emits in the UV wavelength region and has low photostability. Combined, these factors render this naturally occurring fluorescent amino acid hardly useful as a fluorophore for single-molecule measurements (4) and imaging applications, especially under in vivo conditions. For this reason, significant efforts have been devoted to identifying small unnatural fluorophores (5-11) that could overcome this limitation. So far, only naphthalene-based fluorophores, such as prodan (8, 9) and aladan (11) have been shown to be useful in this regard. However, these fluorophores are not structurally based on any naturally occurring amino acids and are larger in size than Trp, making them less attractive in applications where there are stringent requirements for the fluorophore size and structure. Therefore, the development of a smaller, ideally amino acid-based, fluorophore that does not require additional time to mature, have a large fluorescence QY, long fluorescence lifetime, good photostability, and an emission spectrum in the visible range, would enhance biological research. Herein, we show that a Trp analog, 4-cyanotryptophan (4CN-Trp), meets these requirements and has great potential to expand biological fluorescence spectroscopy and microscopy into additional territory.Many past studies have focused on Trp-based unnatural amino acids, including azatryptophans (5, 6, 12) and various indole-ring substituted analogs (13-16), aiming to identify useful biological fluorophores. Whereas some Trp analogs indeed exhibit improved fluorescent properties over Trp, none of them has found broad applications due to certain photophysical limitations. Recently, Ta...

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Utility of 5-Cyanotryptophan Fluorescence as a Sensitive Probe of Protein Hydration

Cited by 46 publications

References 55 publications

Do guanidinium and tetrapropylammonium ions specifically interact with aromatic amino acid side chains?

Do guanidinium and tetrapropylammonium ions specifically interact with aromatic amino acid side chains?

On the positional and orientational order of water and methanol around indole: a study on the microscopic origin of solubility

Blue fluorescent amino acid for biological spectroscopy and microscopy

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