Tao
Wu
* and
Petr
Bouř
Institute of Organic Chemistry and Biochemistry, Academy of Sciences, Flemingovo náměstí 2, 16610 Prague 6, Czech Republic. E-mail: wu@uochb.cas.cz
First published on 24th January 2018
Recently, we found that the Raman optical activity (ROA) technique can be used to monitor even a weak lanthanide luminescence including circular polarization. In the present study we compare circularly polarized luminescence (CPL) spectra of Eu(III), Sm(III), and Er(III) induced by aqueous solution of sialic acid. For Eu providing the strongest signal a chelation model was proposed where the carboxyl adopts the axial conformation and carboxyl oxygen is attached to Eu(III).
The carboxyl group can be at an axial or equatorial position, Neu5Ac thus exists in the α and β anomers (Scheme 1). In solution, the β-anomer is prevalent (over 90%).4,5
Lanthanide(III) ions are used as fluorescent probes designed for analysis and imaging of biological materials because of their unique electronic structures and sensitivity to the environment.6,7 They are also relatively non-toxic and stable under irradiation. Lanthanide probes were found to be useful for the detection of sialic acid by MRI8–10 and luminescence spectroscopic methods.11,12 Recently, circularly polarized luminescence (CPL) was used to indicate the presence of sialic acid, upon chelation with a racemic europium(III) complex.5
Commercial CPL instruments use relatively weak excitation sources, which weakens the sensitivity of this method.13–16 Raman instruments with a stronger laser excitation are usually not suitable for luminescence measurements on organic molecules, because of their limited spectral range. For europium(III), however we found that CPL recording using the Raman optical activity (ROA) spectrometer is quite convenient.17 The metal provides narrow spectral lines that fit into the spectrometer operational range. ROA-based identification of luminescent achiral lanthanide compounds when the chirality is induced by a magnetic field is also possible.18 This was shown for Na3[Ln(DPA)3] complexes, Ln = Ce, Pr, Nd, Sm, Eu, Tb, Dy, Ho, and Er. The ROA/CPL spectroscopy thus seems quite versatile and very promising for future applications in biospectroscopy.
The (vibrational) ROA signal itself is equally useful in molecular structural studies,19,20 but lanthanide CPL is often much stronger. Sugar-based compounds were indicated as particularly suitable for Ln/CPL spectroscopy, providing multiple metal binding groups (mostly OH) and very specific signals21 suitable for their recognition.22 However, many spectral features are not understood, and suitability of different metals for the CPL probing is not systematically explored. In the present study, we compare the optical activity of Eu(III), Sm(III), and Er(III) induced by Neu5Ac. A europium(III) complex was identified as the most promising indicator of the acid.
The Raman/TL and ROA/CPL spectra of plain Neu5Ac solution and mixtures with EuCl3, Sm(NO3)3 and ErCl3 are plotted in Fig. 1. The Neu5Ac Raman spectrum is very rich, reflecting the number of vibrational normal modes; however, its ROA spectrum is rather weak; the ratio of the ROA and Raman intensity (CID, circular intensity difference) is about ∼10−4.
Fig. 1 Raman/TL and ROA/CPL spectra of Neu5Ac (300 mM) and its complexes with EuCl3 (red, 4 mM:4 mM), Sm(NO3)3 (green, 30 mM:30 mM), and ErCl3 (grey, 30 mM:30 mM). |
Compared to this, the CPL signal induced in Eu(III) and Sm(III) is quite remarkable, CID ∼10−2–10−3 (Table 1). On the other hand, Er(III) provides no signal even at high concentrations. This is somewhat unexpected, because at least the 2G9/2 → 4I13/2 erbium transition previously did provide measurable CPL induced by a magnetic field.18 Thus the interaction with Neu5Ac is either weak or does not provide the magnetic and quadrupole components necessary for CPL.
Neu5Ac:Ln | Raman shift (cm−1) | Wavelength (nm) | CID ratio | Transition |
---|---|---|---|---|
EuCl3 | >2450 | 611.7 | 5D0 → 7F2 | |
1974 | 594.4 | 7.38 × 10−3 | 5D0 → 7F1 | |
1901 | 591.9 | −1.92 × 10−2 | 5D1 → 7F3 | |
1897 | 591.7 | |||
1866 | 590.6 | |||
1678 | 584.1 | |||
1656 | 583.4 | −3.47 × 10−3 | ||
1530 | 579.1 | 5D0 → 7F0 | ||
900 | 558.8 | −1.33 × 10−2 | 5D1 → 7F2 | |
851 | 557.2 | 8.66 × 10−3 | ||
802 | 555.7 | |||
761 | 554.4 | 9.29 × 10−3 | ||
725 | 553.3 | −3.94 × 10−3 | ||
Sm(NO3)3 | 2251 | 604.4 | 4G5/2 → 6H7/2 | |
2139 | 600.3 | −9.11 × 10−3 | ||
2038 | 596.7 | 4F3/2 → 6H9/2 | ||
1978 | 594.6 | 3.93 × 10−3 | ||
1969 | 594.2 | |||
1887 | 591.4 | |||
1785 | 587.8 | |||
1106 | 565.3 | −4.13 × 10−3 | 4G5/2 → 6H5/2 | |
1010 | 562.2 | 7.58 × 10−3 | 4F3/2 → 6H7/2 | |
996 | 561.8 | |||
876 | 558.0 | −1.14 × 10−2 |
Both TL and CPL of the EuCl3–Neu5Ac system are very different from spectral shapes observed for EuCl3 in monosaccharide solutions,21 indicating a specific binding mode. Although the Eu concentration is rather low (4 mM), CPL is comfortably measurable as the relative intensity is about 30 times stronger than the ROA intensity of Neu5Ac. For the ROA acquisition, a much larger concentration (300 mM) was needed. The highest CID ratio is −1.92 × 10−2 at 1901 cm−1, corresponding to the 5D0 → 7F1 Eu transition.
The interaction of Neu5Ac with europium was examined in more detail. Both the TL and CPL spectra depend on temperature; colder temperature is favorable for the larger CID ratio (Fig. S1, top, ESI†). Spectral shapes also exhibit some dependence on the concentration, as follows from titration results shown in Fig. 2. The usually extremely weak 5D1 → 7F2 transition is apparent both in TL (802 cm−1) and CPL spectra (900, 851, 761, and 725 cm−1, Fig. 2).23 High CID values at 900 cm−1 (−1.33 × 10−2) and elsewhere suggest a coordination binding between Eu(III) and Neu5Ac. The titration curve (Fig. 2) indicates that one europium ion might bind two Neu5Ac molecules. However, more complex intermolecular interactions may be involved; because the largest CID was obtained for the five to one Neu5Ac/EuCl3 ratio (Fig. S1, ESI†). After this, the CID values slightly decrease, although the intensity of both TL and CPL increases slightly.
The TL intensity of the Sm(NO3)3–Neu5Ac system is much weaker and a higher concentration is needed to obtain good spectra when compared to EuCl3. In accord with a previous study,18 the Sm(NO3)3 nitrate ion provides the peak at 1049 cm−1 and two broad Sm(III) luminescence bands (1969 and 996 cm−1) are observed (Fig. S2, ESI†). As for Eu, Neu5Ac binding to the Sm(III) core is accompanied by induced CPL spectra, composed of more bands compared to magnetic Sm(NO3)3 CPL.18 The largest CID ratio gives the peak at 876 cm−1 (−1.14 × 10−2, Table 1), corresponding to the 4G5/2 → 6H5/2 transition; the ratio is slightly bigger than that for the magnetic CPL.18
Possible binding model geometries of the Neu5Ac and Eu(III) complexes were obtained by the DFT method (Fig. 3). Apparently, both α and β-anomers may form three Eu–O coordination bonds, i.e. with the participation of one COO– (in C1) and two OH (at C2 and C8, respectively) groups. The bond lengths are exemplified in Table 2. The calculation indicates that europium binding to the carboxylic group is stronger than that to the OH groups, and the binding of Eu to the α-anomer is preferred by a relatively high energy margin (5.2 kcal mol−1).
Fig. 3 Optimized geometries of Eu with α- (left) and β- (right) Neu5Ac anomers, relatively free energy is indicated. |
Bond | α-Anomer | β-Anomer |
---|---|---|
Eu-OO(C1)- | 218 pm | 226 pm |
Eu-OH(C2)- | 262 pm | 257 pm |
Eu-OH(C8)- | 241 pm | 247 pm |
The CPL spectra of three lanthanides induced by the sialic acid solution were acquired using the ROA technique and analyzed. No usable signal was detected for erbium, but the induced optical activity of europium and samarium appeared useful for Neu5Ac detection. The titration indicated that one europium ion binds about two ligands. The possible structure of the complex was proposed with the aid of DFT calculation. The rich signal (e.g.5D1 → 7F2, 5D0 → 7F0, and 5D0 → 7F1 europium transitions) of simple chlorides that can be measured on the ROA spectrometer is convenient for many applications, avoiding a relatively expensive synthesis of organic Eu(III) complexes.
This work was supported by Czech Science Foundation (16-08764Y and 18-05770S) and Ministry of Education (LTC17012).
Footnote |
† Electronic supplementary information (ESI) available: Details of the experimental method, the temperature dependent CID ratio of the band at 1901 cm−1 of Neu5Ac:EuCl3; the concentration dependent CID ratio of the band at 1901 cm−1 of Neu5Ac:EuCl3 in aqueous solution; and the Neu5Ac:Sm(NO3)3 spectrum. See DOI: 10.1039/c7cc09463a |
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