Self-Assembly of Telechelic Tyrosine End-Capped PEO and Poly(alanine) Polymers in Aqueous Solution

.


■ INTRODUCTION
−8 In particular, polymers can be synthesized inexpensively and attached to peptides, modifying their solubility and aggregation properties.On the other hand, modification of polymers with peptides provides biofunctionality of many types, depending on the peptide and on the mode of incorporation, i.e., whether laterally attached where the peptide motif forms part of the polymer repeating unit, or whether attached at one or both ends of the polymer.−17 Hydrophilic polymers may be modified with hydrophobic end groups to create telechelic polymers, which among other properties resulting from the noncovalent association of the end groups, possess useful rheological behavior.This is exploited in associative polymers 18−20 widely used as thickeners in a variety of applications, and in commercially available polyethylene glycol (PEG)-based polymers such as reverse Pluronics, 20 for example.In the field of peptide biomaterials, it has been proposed that polymers such as PEG or PEO (poly(ethylene oxide)) may be used as inert spacers within peptide sequences to improve stability and circulation time of the biomolecules for applications such as gene delivery, 21 or cell signaling. 22−26 There are still few papers investigating the properties of selfassembled telechelic peptide−polymer−peptide conjugates.In a recent paper, the Hamley group reported on the gel−sol transition of conjugates of PEO with hydrophobic dipeptides, including dityrosine and diphenylalanine. 17The conjugates were synthesized by coupling the dipeptides to bis-aminopropyl PEO of molar mass 1500 g mol −1 .The Fmoc (N-fluorenyl-9methoxycarbonyl) protecting group (used in the peptide synthesis) was retained in some of the conjugates prepared, at one or both termini.This influences the hydrophile− lipophile balance and hence has a significant effect on the selfassembly behavior.Remarkably, one conjugate comprising dityrosine end-caps and with C-terminal Fmoc was found to undergo a gel−sol transition near body temperature, and this was shown to be driven by the loss of β-sheet secondary structure, associated with the formation of extended fibrils.The Lendlein group later prepared similar telechelic conjugates of desaminotyrosine (DAT) or desaminotyrosyl-tyrosine (DATT) with a linear PEG3000 midblock and also a form arm-PEG conjugate. 27A critical aggregation concentration was noted for the linear midblock conjugate, pointing toward self-assembly at high concentration. 27The rheological properties of hydrogels formed by linear and star-shaped oligo-ethylene glycol/DATT conjugates were examined.The same group also investigated the structural, conformational and rheological properties of gelatin (which has a collagen-based helical structure) functionalized with DAT or DATT at lysine residues. 28,29Micelles have been reported for PLL−PEG−PLL copolymers, where PLL denotes poly(L-leucine), the PLL adopting an α-helical conformation. 30Release of encapsulated drug was also investigated and sustained release over times 100−200 h was observed.Fibrillar hydrogels have recently been reported for a PAla−PGlu−PAla [PGlu: poly(L-glutamic acid)] conjugate selfassembling in aqueous buffer solution. 31n the present paper, we investigate the self-assembly in aqueous solution of conjugates comprising telechelic polymers capped with short (pentameric or trimeric) tyrosine sequences.The creation of tyrosine-functionalized polymers is of interest in the development of novel aqueous biomaterials and hydrogel systems.In contrast to our previous study, 17 the polymers are prepared by living NCA polymerization techniques, which give greater flexibility to tailor block length and which enable here the creation of novel purely peptidic conjugates with a central poly(L-alanine) block.The central core polymer in these designed telechelic conjugates is either PEO with molar mass of 2 kg mol −1 or 6 kg mol −1 or poly(L-alanine).According to most hydrophobicity scales, tyrosine is considered hydrophobic, 32,33 (although not according to the Kyte−Doolittle scale 34 ) and capable of undergoing aromatic stacking interactions.Tyrosine has interesting functionality, as it is involved in cell signaling and is responsive to enzymes including kinases and phosphatases, which add and delete phosphate groups, respectively.It also has interesting fluorescence properties.Alanine is somewhat hydrophilic, at least according to the White−Wimley hydrophobicity scale, 32,33 and so the Tyr 3 -PAla-Tyr 3 conjugate has a hydrophobic−hydrophilic−hydrophobic architecture analogous to that of the two PEO conjugates, although with a purely amino acid based architecture (which may be of relevance to future applications where bioactivity is important).We find using a comprehensive suite of characterization measurements that all three novel conjugates form β-sheet-based fibrillar structures via selfassembly in aqueous solution, although the fibril morphology is distinct for the three conjugates.Unexpectedly, hydrogel formation was not observed up to rather high polymer concentration, enabling the production of high polymer/ peptide conjugate content liquids.The influence of PEO crystallization on drying films is examined for the Tyr 5 -PEO2k-Tyr 5 and Tyr 5 -PEO6k-Tyr 5 conjugates, representing the first study to our knowledge on crystallization in this class of polymer/peptide conjugate that provides insight into PEO crystallization when constrained within a telechelic architecture.

Scheme 1. Synthesis Route for Tyr-PEO-Tyr Samples
Ethylenediamine (≥99%) was obtained from Aldrich and was left to dry over a sodium mirror for 24 h.It was then distilled into precalibrated ampules, diluted with purified DMF to the appropriate concentration, subdivided into ampules, and stored under high vacuum at −20 °C.Thionyl chloride (99.7%, Acros Organics) was distilled prior to use.The solvent purification was performed using standard high vacuum techniques reported elsewhere. 35ynthesis of the novel tert-Butyl protected N-carboxy anhydride of L-Tyrosine (Tyr(tBu)-NCA).See Supporting Information (SI) Scheme S1.Boc-Tyr(tBu)−OH (3 g, 8.9 mmol) was added to a round-bottom flask with a stir bar and dried overnight under high vacuum.Then 30 mL of THF was distilled in the flask, giving a clear solution.The reaction flask was placed in an ice-bath, filled with argon, and 0.95 mL (13.1 mmol) of thionyl chloride diluted in 10 mL of THF was added dropwise in a period of 10 min.The reaction was left at 0 °C for 1 h and at 25 °C for 3 h, giving a clear yellow solution.Then the solution was poured into 700 mL of hexane, and a yellow solid was precipitated.The solid was filtered and then transferred to a roundbottom flask.A quantity 40 mL of ethyl acetate was distilled giving a yellow suspension.The suspension was filtered, and the filtrate was poured into 600 mL of hexane under vigorous stirring.Finally, the white solid precipitate Tyr(tBu)-NCA was isolated by filtration and dried overnight, under high vacuum, to afford 1.85 g (7.0 mmol, 79% yield).The purity of Tyr(tBu)-NCA was confirmed by 1 H NMR and FTIR spectroscopy, shown in Supporting Information Figures S1 and  S2, respectively.
Synthesis of N-Carboxy Anhydride of L-Alanine (Ala-NCA).The synthesis process of the L-alanine NCA (Ala-NCA) was accomplished according to a previously published method. 35ynthesis of Poly(L-tyrosine)-PEO-Poly(L-tyrosine).(a).Synthesis of Tyr 5 -PEO2k-Tyr 5 .PEO bis(amine) (0.57 g; 0.28 mmol) with M n = 2.0 × 10 3 g/mol was added to a round-bottom flask.Twenty milliliters of highly dry benzene was distilled, and the macroinitiator was dissolved.The solution was stirred for 2 h, and benzene was distilled off to dryness.This procedure removes residual water in the PEO, which can initiate NCA polymerization.Subsequently, 20 mL of highly pure DMF was distilled followed by dissolution of the macroinitiator.Then 0.70 g (2.66 mmol) of Tyr(tBu)-NCA, dissolved in 5 mL of DMF, was added.Periodically, the solution was pumped to remove the CO 2 produced from polymerization.After completion of the polymerization (observed when bubbling of THF solution stopped), the polymer was precipitated in diethyl ether and dried under high vacuum.For the deprotection of tBu groups, 36 the copolymer was suspended in CH 2 Cl 2 (20% w/v) and an equal volume of trifluoroacetic acid (TFA) was added along with 0.5 mL of H 2 O.The polymer was completely dissolved and was left to be deprotected for 1 h at room temperature.Subsequently, an equimolar amount (with respect to the number of Tyr monomeric units) of triisopropyl silane was added.The solution was poured into diethyl ether, and the white solid was filtered, dried, diluted in water and dialyzed against 2 L of Milli-Q water for four times.Finally, the polymer solution was freeze-dried to yield Tyr 5 -PEO2k-Tyr 5 as a white powder.The reactions used are given in Scheme 1.
The PEO precursors as well as the final copolymers containing PEO with M n = 2.0 × 10 3 g/mol or 5.9 × 10 3 g/mol were characterized by 1 H NMR spectroscopy (Figure 1) and size exclusion chromatography featuring a two-angle laser light scattering detector (Figure 2).From the FTIR spectrum (Supporting Information Figure S2), it is obvious that the peak of the Boc-protection of the amine groups at 1736 cm −1 is completely eliminated after the formation of the NCA, while the peaks at 1848 and 1741 cm −1 have developed, corresponding to the carbonyl groups of the cyclic N-carboxy anhydride.
Synthesis of Poly(L-tyrosine)−Poly(L-alanine)−Poly(L-tyrosine).Polymerization was carried out with ethylenediamine as the initiator.The sequential addition methodology was used for the synthesis of the triblock polypeptide.Ala-NCA (0.36 g) was diluted in 10 mL of DMF, and 2 mL of ethylenediamine solution in DMF (1.89 × 10 −5 mol/mL) was added.An aliquot of the solution was removed after the completion of the polymerization (2 days) for characterization of the poly(L-alanine) block.Then, 0.05 g of Tyr(tBu)-NCA was then added and was left to react until all monomer was completely consumed.After complete consumption of Tyr(tBu)-NCA (2 days), the final triblock copolymer was precipitated in diethyl ether, filtered, and dried to constant weight.For the deprotection of tBu groups, the same procedure as above was followed.Finally, poly(L-tyrosine)− poly(L-alanine)−poly(L-tyrosine) was produced as a white powder.The reactions used are given in Scheme 2. The final copolypeptide was characterized only by 1 H NMR spectroscopy (Figure 3), since it was not soluble in DMF.
Methods.Size Exclusion Chromatography.Size-exclusion chromatography (SEC) was used to determine the M n and M w /M n values.The analysis was performed using a system that was composed of a Waters 600 high pressure liquid chromatographic pump, Waters Ultrastyragel columns (HR-2, HR-4, HR-5E, and HR-6E), a Waters 410 differential refractometer detector and a Precision PD 2020 two angle (15°, 90°) light scattering detector at 60 °C.A 0.1N LiBr DMF solution was used as an eluent at a rate of 1 mL/min (SEC-TALLS).
NMR and FTIR Spectroscopy. 1 H NMR spectroscopy (300 MHz) was performed using a Varian Unity Plus 300/54 spectrometer.The spectra of the polymers were measured either in deuterated DMSO (NCA and poly(L-tyrosine)-PEO-poly(L-tyrosine)) or in CF 3 COOD (the Tyr 3 -PAla-Tyr 3 copolypeptide).FTIR measurements were performed with a PerkinElmer Spectrum One instrument, in KBr pellets at room temperature, spectra being recorded over the range 450−4000 cm −1 .
Sample Preparation.The solubility of samples dissolved into water was found to be poor but pH adjustment to 12 (above the pK a of tyrosine 37 ) using an NaOH solution led to satisfactory solubility, therefore this was the pH value selected for all measurements for samples Tyr 5 -PEO2k-Tyr 5 and Tyr3-PAla-Tyr3.Since sample Tyr 5 -PEO6k-Tyr 5 was found to show good solubility in water, it was also studied at its native pH, pH 5.69.
Circular Dichroism.CD spectra were recorded using a Chirascan spectropolarimeter (Applied Photophysics, UK) in the wavelength range 190−320 nm.The samples, 0.5% in water raised to pH 12 or native pH for Tyr 5 -PEO6K-Tyr 5 , were placed in a coverslip cuvette (0.1 mm thick), with spectra presented with absorbance A < 2 at any measured point with a 0.5 nm step, 1 nm bandwidth, and 1 s collection time per step.Samples were acclimatized at each increasing 10 °C temperature point for 5 min, and 30 min for the 60−20 °C change, before measurements were taken.The CD signal from the background was subtracted from the CD spectra of the sample solutions.
FTIR.For the secondary structure studies, spectra were recorded using a Thermo Scientific Nicolet IS5 and a Nexus-FTIR spectrometer, both equipped with a DTGS detector.A 40 μL drop of the sample (in D 2 O) was sandwiched between two CaF 2 plate windows, with a 0.006 mm thick Mylar spacer) in a Specac GS20500 sample cell holder.Cells were heated using a Specac 4000 series high stability heating controller, and a Specac electrical heating jacket.The sample was acclimatized at each temperature point for 10 min before measurements were taken.Spectra were scanned 128 times over the range of 900−4000 cm −1 .
X-ray Diffraction.X-ray diffraction was performed on a peptide stalk prepared by drawing a fiber of 1% conjugate solution between the ends of wax-coated capillaries, after separation and drying a stalk was left on the end of one capillary.For some samples, the capillary was mounted vertically onto the four axis goniometer of a RAXIS IV++ Xray diffractometer (Rigaku) equipped with a rotating anode generator (CuK α radiation, wavelength λ = 1.54 Å).The XRD data was collected using a Saturn 992 CCD camera.The sample-to-detector distance was 50 mm.Other measurements were performed on stalks mounted (vertically) onto the goniometer of an Oxford Instruments Gemini Xray diffractometer, equipped with a Sapphire 3 CCD detector.The sample to detector distance was 45 mm.
Small-Angle X-ray Scattering.For the solutions, experiments were performed on ID02 at the ESRF, Grenoble France.Samples were flowed through a quartz capillary.After the sample was injected in the capillary and reached the X-ray beam, the flow was stopped during the SAXS data acquisition.The sample−detector distance was 2m (data were also obtained at 10 m).Data processing (background subtraction, radial averaging) was performed using the dedicated beamline software or SAXSUtilities (http://www.sztucki.de/SAXSutilities/).
For the solid state Tyr 5 -PEO6k-Tyr 5 sample, measurements were performed on BM26B (DUBBLE) at the ESRF (Grenoble, France).Time-resolved DSC, SAXS, and WAXS measurements were performed. 38,39The sample-to-SAXS detector distance was ca.1476 mm using a wavelength of 1.033 Å.A Dectris-Pilatus 1 M detector with a resolution of 981 × 1043 pixels and a pixel size of 172 × 172 μm was used to acquire the 2D SAXS scattering patterns.Standard corrections for sample absorption and background subtraction were performed.The data were normalized to the intensity of the incident beam (in order to correct for primary beam intensity fluctuations) and were corrected for absorption and background scattering.Diffraction from silver behenate was used to calibrate the wavevector scale of the scattering curve.WAXS patterns were collected using a Pilatus 300 K− W detector (linear, 254 mm × 33.5 mm active area) with a pixel size of 172 μm 2 .The wavenumber q = (4π/λ)sinθ scale for the WAXS scale calibration was done using alpha aluminum.The samples were introduced in modified DSC pans pierced in order to produce X-ray windows which were placed in a DSC 600 heating stage from Linkam.The modified DSC pan windows are made of mica, and the capsules were sealed, avoiding sample loss.The sample was heated from −20 to 80 °C to −20 to 80 °C at 5 °C/min, SAXS/WAXS measurements being taken every 30 s.
Rheology.Dynamic shear moduli were measured using a controlled stress AR-2000 rheometer from TA Instruments.A coneand-plate geometry (20 mm diameter, 1°angle) was used for a sample of Tyr 5 -PEO6k-Tyr 5 (20 wt % in water).Stress sweeps were performed first to determine the linear viscoelastic regime.Frequency sweeps were performed with a stress of 4.75 Pa.The angular frequency range was 0.1−622.8rad s −1 , although data are only presented up to 50 rad s −1 due to device inertia at high frequency.
The viscosity of the sample was measured performing varying stress experiments in the range 0.0056 to 16880 s −1 .
Polarized Optical Microscopy.Images were obtained with an Olympus BX41 polarized microscope by placing the sample between crossed polarizers.Films were prepared by drying 40 μL of 1 wt % peptide.Dry films were placed between a glass slide and a coverslip before capturing the images with a Canon G2 digital camera.

■ RESULTS
The molecular characteristics of the polymers synthesized are shown in Table 1.In the case of the two PEO-containing polymers, the molecular weights were obtained by SEC-TALLS.The composition of the final copolymers obtained was in excellent agreement with the stoichiometric molecular weights as well as the composition obtained by 1 H NMR spectroscopy.The molecular weight of the PTyr-b-PAla-b-PTyr copolypeptide was obtained from the ratio of integral of the NMR signal from the protons of the initiator and those of the poly(L-tyrosine) and poly(L-alanine).Due to the low molecular weight of the blocks, it was possible to obtain the accurate molecular weights, which were in good agreement with the stoichiometric ones.This reveals the copolymer contains three tyrosine residues at each terminus, so the polymer is henceforth named Tyr 3 -PAla-Tyr 3 .
−44 The benzyl groups are usually deprotected utilizing HBr in acetic acid.These conditions are so acidic that almost all protecting groups that are treated under acidic conditions are cleaved, and therefore, these conditions cannot be utilized selectively if an amphiphilic copolypeptide bearing a protected as well as a free residue is to be synthesized.It is well known that the tert-butyl group can be cleaved under mild conditions in the presence of TFA. 36Although during the synthesis of the NCA of tyrosine HCl is produced, we found that it did not influence the tert-butyl protective group.We found that TFA was an effective reagent to quantitatively remove the tertprotecting group of the hydroxyl group of tyrosine, while, under these conditions, several other protective groups remain intact.Therefore, the novel monomer that we present in this work can be used effectively for the selective deprotection of tyrosine (Supporting Information, Scheme S1).
The secondary structure of the peptide components of the conjugates was examined using a combination of circular dichroism (CD) and FTIR spectroscopy.Figure 4 shows CD spectra.The temperature dependence of the CD data was examined in the range 20−60 °C, and no significant changes in the CD spectra were noted for either Tyr 5 -PEO2k-Tyr 5 or Tyr 5 -PEO6k-Tyr 5 (Figure 4a,b).For Tyr 5 -PEO6k-Tyr 5 at native pH (pH 5.69), the spectra (Figure 4a) show a minimum at 218 nm, which is a signature of β-sheet structure.The maximum at 228 nm is due to the absorbance of the tyrosine residues, similar features having been observed for a Tyr 2 -PEO1.5k-Tyr 2 conjugate, 17 YYKLVFF-PEG conjugates with PEG1k or PEG3k, 45 as well as dityrosine containing peptides. 46he spectra for Tyr 5 -PEO6k-Tyr 5 at pH 12 (Figure 4b) are qualitatively similar in shape to those at native pH, but with reduced molar ellipticity values pointing to reduced secondary structure content.For Tyr 5 -PEO2k-Tyr 5 , the spectra shown in Figure 4c do not extend as low in wavenumber as those for Tyr 5 -PEO6k-Tyr 5 , due to observed absorption effects but the shape resembles that for the latter conjugate, but with a red shift such that the minimum is at 220 nm and the maximum due to the tyrosine aromatic units is at 244 nm.The spectra for Tyr 3 -PAla-Tyr 3 in Figure 4d show a minimum at 226 nm, which can also be assigned to a red-shifted β-sheet structure. 47There is no maximum at higher wavelength due to the tyrosine units, which is presumably because the contribution from these groups is overwhelmed by the poly(L-alanine) midblock with   approximately 64 alanine repeats.There is a reduction in βsheet content on heating leading to a conformational state retained on cooling as the sample approaches its equilibrium state.There is no evidence for helical structure of PAla in the CD spectra, which is consistent with the analysis of the XRD data (vide inf ra) from this sample.The FTIR spectra measured for all three polymers presented in Figure 5 show features in the amide II′ region (NH 2 deformations) around 1500 cm −1 and, most informatively, in the amide I′ region which provides information on peptide secondary structure via the CO deformation modes.The spectrum for Tyr 3 -PAla-Tyr 3 shows a peak at 1623 cm −1 , consistent with the β-sheet structure of polyalanine-rich peptides (previously observed at 1626 cm −1 for an argininecapped alanine oligomer 48 ), with a β-sheet assignment also for the 1635 cm −1 peak for Tyr 5 -PEO2k-Tyr 5 . 49,50For Tyr 5 -PEO6k-Tyr 5 , there are no defined peaks in the amide I′ region (for samples at either native pH or at pH 12), which prohibits assignment of secondary structure.It is believed that this is due to the absorbance of the longer PEO chain in this compound overwhelming the signal from the peptide end groups.For all samples, the large observed peak near 3400 cm −1 is consistent with −OH stretch deformations of hydrogen-bonded carbonyl groups in PEO or poly(L-alanine) and the peak at 2930 cm −1 is assigned to PEO −CH 2 or poly(L-alanine) backbone −CH deformation modes. 51iber X-ray diffraction on dried stalks was used to investigate the molecular ordering.The fiber X-ray diffraction patterns from all samples were found to be isotropic and were reduced to one-dimensional form.The resulting intensity profiles are shown in Figure 6.These show peaks at 7.49, 5.27, 4.36 and 3.71 Å for Tyr 3 -PAla-Tyr 3 .These are very similar to those we have reported for oligo(alanine) peptides and are assigned to the unusually tightly packed β-sheet structure of alanine-rich peptides 35,48,52 with a β-strand spacing of 4.36 Å and an intersheet spacing of 5.27 Å.The XRD data in Figure 6 indicate that there is also β-sheet content in Tyr 5 -PEO2k-Tyr 5 , due to the presence of the 4.69 Å reflection, 50,53 along with some others that are assigned to semicrystalline PEO.That PEO is semicrystalline is shown by the presence of a broad peak due to amorphous polymer, upon which the crystal peaks are superposed.The expected d-spacings for the strong reflections (indicated Miller indices) from crystalline PEO are 54  In studies of PEO−peptides comprising KLVFF-based peptides and PEO of different molar mass, we have found that PEO crystallization is modulated by the fibril-forming propensity of the peptide, for instance, in conjugates with a fixed PEO molar mass (PEO3k), crystallization was observed for the weak fibrillizing peptide KLVFF, but not for the strong fibrillizer FFKLVFF. 55,56These studies, together with an investigation that compared the structures of FFKLVFF−PEOs with different PEO molar mass (1k, 2k, and 10k), 57 suggest that PEO2k may be close to the molar mass threshold to exhibit some crystallinity.This is consistent with the data in Figure 3 for Tyr 5 -PEO2k-Tyr 5 , which shows some PEO crystallinity (but to a low extent) along with β-sheet structure from the Tyr 5 end groups.On the other hand, the peaks in the X-ray intensity profiles for Tyr 5 -PEO6k-Tyr 5 in Figure 3 are not consistent with β-sheet order (there is no peak that can be assigned to the β-sheet stacking distance) and instead can be assigned to peaks from highly crystalline PEO.In fact, there are shifts from the expected peak positions listed above, which is assigned to the influence of the Tyr 5 end groups on the PEO unit cell dimensions.A detailed examination of this interesting effect whereby PEO crystallization is modified by the presence of small peptide end groups is outside the scope of the present paper.The findings concerning PEO crystallization for the sample containing PEO6k are consistent with expectations based on the PEO molar mass, and with images of dried films of the samples to be discussed shortly.The same XRD pattern is obtained for stalks dried from Tyr 5 -PEO6k-Tyr 5 at native pH or at pH 12 (data not shown).
Cryo-TEM was used to image self-assembled nanostructure.Figure 7 shows representative images.For Tyr 5 -PEO6k-Tyr 5 , the presence of short, very straight fibrils approximately 5 nm in diameter extending to a few hundred nm in length is clear, these coexisting with shorter (and nearly spherical) nanostructures of similar diameter.For Tyr 5 -PEO2k-Tyr 5 , cryo-TEM reveals clusters of short fibrils.SAXS data (Figure 8) clearly supports the presence of fibrillar structures.A similar structure of local clusters of fine fibrils/filaments was also observed for Tyr 3 -PAla-Tyr 3 .These observations are consistent with the presence of β-sheet structures (which are typically present in extended fibrils) for these samples, as revealed by spectroscopic methods, as discussed above.The difference in appearance of the fibrils of Tyr 5 -PEO6k-Tyr 5 is striking as they are extremely straight.Similar straight fibrils have previously been observed for Phe 4 -PEO5k 58 and suggest that such short straight fibrils are  favored when the PEO chain length is in the range PEO5k− PEO6k, whereas more flexible fibrils, also termed "wormlike micelles", are observed for diblock conjugates of PEO (molar mass 0.5−1.8kg mol −1 ) to Phe 4 . 59all-angle X-ray scattering measurements were performed to provide further information on the dimensions of the cylindrical fibrils.The measured data along with form factor fits are shown in Figure 8.The data were fitted to a cylindrical core−shell form factor since there is a noticeable change in slope of the intensity profiles near q = 0.3 Å −1 .The fit parameters are listed in Table 2.The core radius for both Tyr 5 -PEO2k-Tyr 5 and Tyr 5 -PEO6k-Tyr 5 is R = 1.03 nm and R = 2.28 nm respectively, which is consistent with the core comprising Tyr 5 plus some of the inner part of the PEO chains, since the estimated length of a Tyr 5 sequence in a βstrand is 5 × 0.32 nm = 1.6 nm only (using the 3.2 Å translation per residue expected for a parallel β-sheet structure 37 ).This radius is consistent with that estimated from the cryo-TEM images for Tyr 5 -PEO6k-Tyr 5 (Figure 7).As expected, the shell radius is lower for Tyr 5 -PEO2k-Tyr 5 compared to Tyr 5 -PEO6k-Tyr 5 (ΔR = 1.92 vs 2.20 nm).The estimated radius of gyration of PEO6k is R g = 2.6 nm and of PEO2k is R g = 1.5 nm (based on a segment length b = 5.6 Å, 60−62 Hammouda and Ho report b = 5.8 Å 63 ).The values of ΔR from the core−shell cylinder form factor fit are close to these values, but are not identical due to the fact that the core radius R includes some of the inner PEO chains, as mentioned above, and there may also be some expansion of the PEO2k chains, in particular in the fibril corona.
We also examined possible gel formation by inspection of samples, followed by shear rheometry of concentrated liquids.It was observed that neither Tyr 5 -PEO6k-Tyr 5 (native pH or pH 12) nor Tyr 5 -PEO2k-Tyr 5 form a gel up to 20 wt % (sample Tyr 3 -PAla-Tyr 3 is not soluble at high concentration so gel formation is precluded).Figure 9 shows measurements of     dynamic shear modulus for a viscous 20 wt % solution of Tyr 5 -PEO6k-Tyr 5 .Stress sweeps (Figure 9a) showed approximately linear viscoelastic behavior up to a stress σ = 10 Pa.Frequency sweeps were then performed, and the results at two different stress values are shown in Figure 9b.These reveal frequencydependent moduli G″ > G′ (and low values of both moduli) consistent with a predominantly fluid-like response.This conclusion is supported by the observed terminal scalings of the moduli G′ ∼ ω 2 and G″ ∼ ω 1 . 64The lack of observed gel formation by Tyr 5 -PEO6k-Tyr 5 even with conjugate concentration up to 20 wt % in aqueous solution may be contrasted with the prior observation of hydrogel formation (at 6 wt %) by NH 2 -Tyr 2 -PEO1.5k-Tyr 2 -Fmoc; 17 however, the Fmoc (Nfluorenyl-9-methoxycarbonyl) unit has a substantial influence on the hydrophobicity of this conjugate and hence on its ability to form a hydrogel.Also hydrogel formation has been observed for a 10 wt % solution of PAla-PGlu-PAla [PGlu: poly(Lglutamic acid)] in buffer solution 31 although this has a charged midblock and different block sequence to our conjugates.
Figure 9c shows the shear rate dependence of the viscosity for the Tyr 5 -PEO6k-Tyr 5 conjugate.This shows a Newtonian regime up to approximately γ̇= 0.1 s −1 , followed by a shearthinning regime with an initial power-law Ostwald-de Waele 65 behavior, η ∼ γ̇− 0.5 .Similar shear-thinning behavior is observed for conventional associative polymers and solutions of wormlike micelles. 64s well as examining the self-assembly of the conjugates in aqueous solution, the behavior of the Tyr 5 -PEO6k-Tyr 5 sample that exhibits PEO6k crystallization on drying was investigated in more detail in the solid state.Figure 10 shows results from synchrotron SAXS/WAXS samples on a dry sample.SAXS and WAXS (Figure 10a,b) show that the first melting of PEO occurs at 52 °C, which is a typical value for the melting temperature T m for PEO with a molar mass of 6 kg mol −1 . 66On cooling, crystallization is observed to start at 50 °C and the second melting at 52 °C.These results indicate a low degree of hysteresis in the melting/crystallization behavior.After the second crystallization, the SAXS data (Figure 10c) shows a broad peak centered at q* = 0.5 nm −1 consistent with the presence of crystalline lamellae, 67−69 but there was no evidence for microphase separation in the melt state.The crystalline lamellar period is 12.6 nm, which indicates significant extension of the PEO chains compared to the conformation in aqueous solution discussed above.Actually, the chain length of PEO in Tyr 5 -PEO6k-Tyr 5 can be estimated as l = 0.095z EO where 0.095 Å is the length per atom along the PEO helix and z EO is the number of atoms 70 (here 136 × 3, where N = 136 is the degree of polymerization), yielding l = 38.8nm.Comparison of this to the measured value of the crystal period points to chain folding of the PEO. Figure 10d shows the WAXS profile in the crystalline state for comparison to the fiber XRD data shown in Figure 6.
These findings concerning PEO crystallization were supported by polarized optical microscopy (POM) images from dried films, shown in Figure 11.For Tyr 5 -PEO6k-Tyr 5 , under native pH conditions there is clear evidence for the presence of crystal spherulites for the dried sample whereas the sample dried from pH 12 exhibits much smaller and less extensive crystallites.Partial crystallinity with poorly developed spherulites was observed for Tyr 5 -PEO2k-Tyr 5 at pH 12, consistent with the WAXS data.

Figure 1 . 1 H
Figure 1. 1 H NMR spectrum of the Tyr 5 -PEO2k-PTyr 5 triblock copolymer.Two sharp solvent peaks are assigned to DMSO at 2.54 ppm and one from water in DMSO at 3.33 ppm.71

a
Obtained by SEC-TALLS.b Obtained by 1 H NMR. c Obtained by SEC-TALLS and confirmed with 1 H NMR.

Figure 5 .
Figure 5. FTIR spectra for 1 wt % samples.For all samples, the pH was adjusted to 12, except where stated.

Figure 6 .
Figure 6.X-ray diffraction data obtained from stalks dried from 1 wt % solutions, as indicated.

Figure 9 .
Figure 9. Dynamic shear modulus measured for a 20 wt % solution of Tyr 5 -PEO6k-Tyr 5 (native pH): (a) stress sweeps at two angular frequencies, ω, indicated; (b) frequency sweep at two stress values indicated.(c) Shear rate dependence of the viscosity.

■
SUMMARY AND CONCLUSIONSAll three oligo(tyrosine)−polymer−oligo(tyrosine) conjugates self-assemble into β-sheet fibrillar structures as shown by a combination of spectroscopic, scattering and microscopy methods.The amide I′ FTIR spectrum for Tyr 5 -PEO6k-Tyr 5 did not show the typical peak for β-sheet structure (probably due to the dominant contribution from unordered PEO6k), but

Figure 10 .
Figure 10.Simultaneous synchrotron X-ray scattering from Tyr 5 -PEO6k-Tyr 5 in the solid state: (a) temperature ramp SAXS data, (b) simultaneous temperature ramp WAXS data, (c) SAXS data on first cooling at 18 °C, and (d) WAXS data on first cooling at 18 °C.

Figure 12 .
Figure 12.Schematic self-assembled structure showing tyrosine fibrillar network linked by PEO or PAla chains with bridging and looping conformations.

Table 1 .
Molecular Characteristics of the Synthesized Polymers