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The Decisive Role of Hydrophobicity on the Effect of Alkylammonium Chlorides on Protein Stability: A Terahertz Spectroscopic Finding Debasish Das Mahanta, Rajib Kumar Mitra, and Nirnay Samanta J. Phys. Chem. B, Just Accepted Manuscript • DOI: 10.1021/acs.jpcb.7b04088 • Publication Date (Web): 25 Jul 2017 Downloaded from http://pubs.acs.org on July 31, 2017

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The Journal of Physical Chemistry

The Decisive Role of Hydrophobicity on the Effect of Alkylammonium Chlorides on Protein Stability: A Terahertz Spectroscopic Finding Debasish Das Mahanta, Nirnay Samanta, Rajib Kumar Mitra*

Chemical, Biological and Macromolecular Sciences S. N. Bose National Centre for Basic Sciences Block-JD, Sector-III, Salt Lake, Kolkata, 700106, India Phone: 91-33-23355706, Fax: +91-33-23353477

* Corresponding author. E-mail: [email protected] (RKM)

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Abstract Many biologically important processes involve a subtle interplay between Columbic and hydrophobic interactions among molecular groups with water. A comprehensive understanding of such processes, specially while occurring simultaneously in the same molecule is of practical importance. In this contribution, we report the ultrafast (sub-ps to ps) collective hydrogen bond dynamics of water in the extended hydration layers in a series of alkylammonium chloride salts using THz time domain spectroscopic (TTDS) technique (0.3-1.6 THz (10-55 cm-1)). We found the THz absorption coefficient (α) of the salt solutions systematically vary with the salt type. We obtain the hydrogen bond relaxation dynamics by fitting the frequency dependent dielectric constants in a multiple Debye dielectric relaxation model. We found these salts to transform from being a water ‘structure breaker’ to ‘structure maker’ with increasing carbon content. We also investigate their effect on a model protein ‘bovine serum albumin’ and found a systematic trend towards disrupting the protein secondary structure. The associated changes in the protein hydration in presence of these salts have also been investigated using TTDS.

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Introduction Non-polar hydrophobic molecules in water are believed to increase disorder due to their inability to form H-bond with the polar water molecules.1 However, they can also enhance the ordering in their surrounding water network.2 The notion of hydrophobic hydration, still a popular topic of research, is highly specific on the solute type and dimension. Small hydrophobic solutes either get arrested within the polyhedral cage formed by the under- or un-coordinated water molecules with dangling O-H bonds2-3 or, the solutes as well as the solvent separately aggregates to form clusters4 with enhanced H-bond network. Larger solutes can even disrupt the tetrahedral network of water. In both the cases there exist defects in the water H-bonded network,3 which is the key driving factor that governs most of the physicochemical and biological processes.5-9 Likewise, ion-water interaction also plays important role in biology and chemistry.10-11 Electrolytes perturb the H-bonded structure in liquid water, thereby either strengthening12-13 or rupturing the water network,12, 14 the extent being highly ion specific in nature.15-17 Bakker et al. have shown that hydration dynamics of ions is cooperative in nature and depends on the hydration of the counter ions also.18 THz spectroscopic investigation by Havenith et al.19-20 established a strong correlation between hydration dynamics and the ‘rattling’ motion of metal ions. A direct correlation between H-bonding and water structure making/breaking ability of ions is highly debatable. Strongly hydrated ions tend to align the static dipoles of their surrounding water molecules. Such effect could be extended beyond the second or third solvation shell of the ions.12, 21 Structural information on ion hydration has so far been realized using neutron and Xray diffraction,22 X-ray absorption spectroscopy,23 IR and Raman spectroscopy24 while the corresponding dynamics has been revealed using various techniques including fs IR pump-probe spectroscopy,18, 25 broadband dielectric spectroscopy,26-27 2D IR vibrational echo experiments,2829

optical Kerr rotation spectroscopy30 vibrational sum frequency generation spectroscopy31-32

and various computer simulation studies.13, 33-34 Instead of understanding electrostatic and hydrophobic interactions individually, it is of practical importance to study them while operating simultaneously. In this regard, cations consisting of water repelling moieties have recently attracted attention among researchers owing to their unique hydration behaviour.32,

35-39

Alkylammonium halides are the most extensively

studied salts that possess the rare combination of ionic and hydrophobic characters in the same 3 ACS Paragon Plus Environment

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molecule, with a tuneable hydrophobicity. Such molecules contain short chain alkanes and unlike amphiphilic molecules do not usually aggregate at moderate concentrations.36 There have been several studies about the physical nature of water around these molecules using various experimental and simulation techniques.37, 40-44 These studies have questioned the popular belief of enhanced H-bonded ‘ice-like’ structure of water around these solutes45-46 concluding that the hydration structure does not suffer considerable perturbation compared to that of pure water in case of short chain alkylammonium halides. However, such effects are found to be prominent for n≥341 (n is the number of carbons in the alkylammonium cations). Earlier simulation studies have also concluded enhancement of water structure around alkylammonium ions.47-48 Buchner et al. have made a detailed dielectric relaxation (DR) study (0.2-89 GHz frequency region) in order to obtain both solute and solvent dynamics in a series of n-alkylammonium salts solutions.37 They found that up to n=2, the effect of these ions on water dynamics is not significant, while for propyl and t-butyl salts the effect is noticeable. These hydrophobic cations, however, show marked contrast when compared to alkali metal cations. A simple consideration of the increased size of the cations49 does not suffice to explain this behavior.42 Beauchamp et al. have shown that ions can as well influence hydrophobic effect.50 While most of these previous studies are rather concerned with the rigidly bound first solvation shell hydration, relatively less attention has been paid to the long-range H-bond cooperative relaxation dynamics. A recent simulation study has revealed the existence of strongly oriented water molecules in the first solvation shell of tetra-methylammonium cations, the effect being lost in the subsequent hydration shells.43 Experimental validation of whether such effect is at all experienced beyond the first solvation shell, specially for larger carbon containing cations, certainly demands attention. Intermolecular rotational and vibrational modes of water, which extends beyond the first solvation shell, produce their signature in the THz frequency region51-52 enabling to study collective hydration dynamics in complex systems.4,

14, 20, 53-57

Due to its low energy, THz

radiation leaves biomolecules unperturbed and the extracted timescale can probe the ultrafast (ps to sub-ps) dynamics of their extended hydration shells.56, 58-60 With the advantage of measuring both the phase and the amplitude of the transmitted radiation in a single experiment this technique infers microscopic information about the cooperative H-bond dynamics of water around solutes and bio-molecules.56, 58-61 Results obtained using this technique could often been 4 ACS Paragon Plus Environment

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found to be complementary to many other conventional techniques, specially to the low frequency Raman scattering technique, which extract pivotal information from biologically relevant molecules.62 Recently our group has studied H-bond relaxation dynamics around alkali metal ions and found these cations to accelerate the water cooperative dynamics and the magnitude of such effect is not a mere linear manifestation of the cation radius.14, 56 We also investigated such dynamics in amino acid solutions and evidenced the formation of ordered water network around them depending upon the hydrophobic or hydrophilic nature of their side chains.57 It stands interesting to investigate how such dynamics is modified as hydrophobicity is introduced into ions. We try to explicitly address the concern whether such ions exert any direct or indirect effect on proteins. Such interactions are important and yet highly debatable in chemical biology.63-64 In the present investigation we choose a well studied model protein bovine serum albumin (BSA) and a series of alkylammonium chlorides salts: tetra-methylammonium chloride (Tetra-MAC), tri-ethylammonium chloride (Tri-EAC), tetra-ethylammonium chloride (Tetra-EAC) and tetra-propylammonium chloride (Tetra-PAC). We measure the stability of the protein in presence of these salts using circular dichroism (CD) spectroscopy. We found that salts with higher hydrocarbon content do perturb the stability of the native protein. This observation is intriguing and leads us to enquire whether this destabilization is associated with any change in the H-bond structure of water. We explore the water structure around these salts using FTIR and THz time-domain spectroscopy (TTDS, in 0.3-1.6 THz region). The extracted optical parameters are fitted in a multiple Debye DR model to obtain the dynamics of water in presence of these salts. We fix Cl- as the counter anion so as to compare the effect solely arising out of the cations only.14 It can also be noted here that DR of water dipoles are mostly dominated by the cations while the dependency is only subtle for anions.38 We observe contrasting cooperative water H-bond making or breaking behaviour. We also notice the proficient effect of tetra-EAC on the protein stability compared to that of tri-EAC, with the latter one differ by only one ethyl moiety. We estimate the effect of these two ions on the long range cooperative protein hydration dynamics using TTDS measurements. As a control we also study the effect of essential electrolyte molecules NaCl, CsCl (as Cs+ has comparable size to that of tetra-MA cation) and a well-known protein denaturant molecule, guanidinium hydrochloride (GdmCl).56 Our study is aimed investigate the extent of hydrophobic hydration in alkylammonium chloride as a function of alkyl chain content and understand their effect on a model protein. The present study has 5 ACS Paragon Plus Environment

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unambiguously pointed out towards the decisive role of hydrophobicity over the electrostatic interaction in protein hydration.

Materials and Methods All the chemicals (scheme S1, supporting information section) were of the highest available purity purchased from Sigma-Aldrich and were used without further purification. We used MilliQ water to prepare the stock solutions. Protein solutions were prepared in sodium phosphate buffer (10 mM) at pH 7.0. Fourier transforms infrared (FTIR) spectroscopy measurements were carried out in a JASCO FTIR-6300 spectrometer using CaF2 windows with 25 µm thick spacer in the mid-infrared (MIR) region (2200-2800 cm-1). HOD samples were prepared by vigorous mixing of 4% D2O in pure water. Each measurement consisted of 100 scans acquired at 0.5 cm-1 resolution. All the data represented in this study are difference absorbance spectrum with pure salt/water aqueous solutions used as the reference. THz time domain spectroscopy (TTDS) measurements were carried out in a commercial THz spectrophotometer (TERA K8, Menlo System)56, 65. In brief, a 780 nm Er-doped fiber laser (˂100 fs pulse width, 100 MHz repetition rate) is alienated into a pump and a probe beams of equal power (10 mW). The pump beam excites the THz emitter antenna producing a THz radiation having a bandwidth of ~ 3.0 THz (> 60 dB). After transmitting through the sample cell, this THz radiation is focused on a THz detector antenna which is gated by the probe laser beam. The THz antennas are gold dipoles with a dipole gap of 5 µm deposited on LT-GaAs substrate. To avoid water vapour absorption, the entire THz set up is purged with dry nitrogen atmosphere with a controlled humidity of