"Soldier-Sergeant-Soldier" triblock copolymers : revealing the folded structure of single-chain polymeric nanoparticles

‘‘Soldiers–Sergeant–Soldiers’’ experiments performed on single-chain polymeric nanoparticles (SCPNs) with an ABA-type triblock architecture carrying chiral and achiral benzene-1,3,5-tricarboxamides (BTAs) in different blocks reveal that the BTAs form segregated, multiple stacks in a single SCPN.

Single-chain polymeric nanoparticles (SCPNs), which are synthetic polymers capable of folding into nanoparticles by covalent/ supramolecular interactions, attract considerable interest to mimic biomaterials. [1][2][3] We have recently developed SCPNs consisting of a synthetic polymer chain with complementary hydrogen-bonding side groups that can induce a large chain collapse through intramolecular self-assembly providing dynamic crosslinking. 4,5 Our investigations on SCPNs predominantly focused on systems with ureidopyrimidinone (UPy) 4 and/or benzene-1,3,5-tricarboxyamide (BTA) 5 as the supramolecular crosslinking units. BTA is a well-explored discotic molecule that forms a helical aggregate, stabilized by threefold, lateral hydrogen bonding. 6 The folding behaviour of BTA-based SCPNs has been investigated extensively by our group for facile construction of nanometer-sized objects ( Fig. 1a), with the ultimate aim to create artificial enzymatic systems. 5b-d Since a better understanding of the folding process is crucial for tailoring the structure and functions of SCPNs, a quantitative estimation of the extent of folding was attempted by means of model analysis of temperature-dependent circular dichroism (CD) spectra. 5d However, gathering direct experimental evidence on the internal folding structure still remains challenging since we are neither able to quantify the length of BTA stacks formed in SCPNs nor to distinguish between single and multi-domains present in the folded core. Using a combination of scattering methods, we recently realized that water-soluble BTA-based SCPNs adopt ellipsoidal shapes with an unexpectedly high aspect ratio. 5f Increasing the degree of polymerization of the SCPN resulted in an increase of the aspect ratio while the cross-sectional radius remained constant. As a result, we concluded that the BTA moieties self-assemble into separate, individual stacks providing multiple, folded domains alongside the backbone polymer. 5h In SCPNs designed for organic solvents, where the hydrophobic effect is absent, it remained unclear how BTA aggregation occurs and how it affects the global conformation of the polymers. 5a Here we report intramolecular ''Soldiers-Sergeant-Soldiers'' (S-S-S) experiments using SCPNs with triblock architectures as a novel tool to elucidate the folding behavior of SCPNs in organic media. To investigate the extent of supramolecular self-assembly, the S-S-S experiment is a powerful tool that has been applied to a variety of self-assembling motifs including BTAs. In ''free'' BTA systems (not bound on a polymer chain), it is known that only 5 mol% of Sergeant BTA, which possesses chiral side chains at the periphery, induces full chiral amplification of the achiral BTA stacks. 6a This indicates that one chiral BTA imposes its preferred handedness on twenty achiral BTAs on average. Thus, in a SCPN the S-S-S experiment provides experimental evidence for the possibility of the chiral sergeant transferring its helical preference to the achiral soldiers.
The chemical structures of S-S-S folding triblock copolymers are depicted in Fig. 1b. The ABA-type triblock copolymers were designed to be so-called ''Soldier-Sergeant-Soldier'' architectures. Sergeants of chiral BTA (B*) and Soldiers of achiral BTA (B) are separately incorporated into the middle (B) and both end (A) blocks, respectively. The subscripts B and * denote BTA and the presence of a chiral center in the peripheral side chains, respectively. We synthesized the S-S-S triblock copolymers with three different molecular weights ranging from 32 to 120 kg mol À1 , denoted as Pn[BB*B] (n = 1, 2, and 3). The triblock architectures were first realized by two-step atomtransfer radical polymerization (ATRP) in the presence of the Cu(I)Br/N-butyl-2-pyridylmethanimine catalyst with isobornyl methacrylate and 10 mol% of post-functionalizable comonomers (propargyl methacrylate for the middle block, and hydroxyethyl methacrylate for both end blocks). The backbone triblock copolymers were functionalized through two consecutive Cu(I)-catalyzed azidealkyne cycloaddition (CuAAC) for B* and ester conjugation reactions for B. † 5e Sergeant fractions, f B* , are around 37% for all S-S-S copolymers. For comparison, triblock copolymers with all chiral BTAs, denoted as Pn[B*B*B*] (n = 1, 2, and 3), were prepared in an identical manner starting with the identical backbone polymers, but now f B* is 100% (Fig. 1a). The characterization data for all triblock copolymers are given in Table 1. A number of possibilities can be distinguished with respect to how the chiral amplification behavior takes place in the single polymer chain. If full chiral amplification occurs, we expect to observe an identical CD signal intensity between Pn[BB*B] and Pn[B*B*B*] at a fixed BTA concentration. If not, a smaller CD signal of Pn[BB*B] compared to that of Pn[B*B*B*] indicates that the formation of only a single, long BTA stack in the SCPN is no longer realistic, neither with segregated nor with intercalated cores ( Fig. 2a and b). In the latter case, the most likely option is an internal structure that consists of multiple cores, in which communication between B* and B is restricted in the individual stacks resulting in no or poor chiral amplification (Fig. 2c).
Temperature-dependent CD measurements using 1,2-dichloroethane (DCE) as a solvent were applied to Pn[BB*B] and Pn[B*B*B*] at a fixed BTA concentration of c BTA = 50 mM (Fig. 3). The polymer solutions were heated up to 80 1C, then slowly cooled down to 20 1C at the rate of 1 1C min À1 to ensure that BTA self-assembly is under thermodynamic control. The CD signal intensity was monitored at 225 nm. Above 60 1C, all of the polymers were CD-silent, indicating that the polymers were molecularly dissolved and adopted unfolded conformations (Fig. 3a, c and e). Upon cooling, a negative Cotton effect was observed for all of the polymers, indicative of the preference for left-handed helical  Fig. S1-S3, ESI). 5e b Sergeant fraction: n B* /(n B + n B* ). c Determined by SEC using THF as the eluent, calibrated using polystyrene standards (Fig. S4, ESI). Ð = M w /M n .  columnar aggregates inside the polymer, which is in accordance with our previous reports. 6 The temperature at which the CD signal starts to appear, T e (elongation temperature), was 60 1C for all polymers, Pn[B*B*B*] and Pn [BB*B]. This confirms that the same incorporation density of BTAs (10 mol%), either B or B*, was achieved in both polymers, since T e is dependent on the local concentration of BTA units. 5a Evaluation of the CD cooling curves shows that the CD signal intensities of all S-S-S polymers Pn[BB*B] never reached the ones of Pn[B*B*B*], indicating that the chiral amplification is not perfectly operative within the triblock architectures, despite the fact that the local Sergeant fraction, f B* , is high (36-37%) and well above the required 5% for free BTAs. The magnitude of the CD effects at room temperature, on the other hand, are higher than the values expected when only chiral BTAs contribute to the CD effect. As a result, the chiral and achiral BTAs mix, but the perfect polymer conformations presented in Fig. 2a  The CD intensity at 225 nm measured at 20 1C after cooling from 80 1C in DCE (c BTA = 50 mM) was plotted for all above polymers as a function of f B* (Fig. 4a). CD spectra and cooling curves of all these polymers are given in Fig. S5. † The plot showed a peculiar non-linear dependence on f B* . In particular, P3[BB*B] (orange marker) with the highest incorporation density of B but the lowest f B* of 37% showed a stronger signal and exhibited the most pronounced double-peak CD spectrum in this polymer series. † This fact could suggest that the inter-block communication starts taking place at a higher incorporation density of B.
Taking all observations into account, we propose a folded structure of BTA-based SCPNs that consists of multiple stacked BTA aggregates (Fig. 4b). As a direct result, the organosoluble copolymers are likely to adopt an ellipsoidal, elongated shape, similar to their watersoluble counterparts. 5f,h The CD cooling curves of P1-P3 are almost identical, indicating that the length of the polymers does not affect the melting curves. This observation implies a lack of strong cooperativity in the folding of these polymers. 5h In conclusion, we have demonstrated ''Sergeant-and-Soldiers'' experiments in the BTA-based SCPNs with a ''Soldier-Sergeant-Soldier'' triblock architecture. The results revealed that BTA units incorporated into the polymer chain tend to form segregated, multiple stacks in the SCPNs with some mixing of the BTA units of the different blocks.
N.H. is thankful to the Japan Society for the Promotion of Science (JSPS) for a Young Scientist Fellowship. This work was financially supported by the European Research Council (ERC), the Dutch Science Foundation (NWO) and the Dutch Ministry of Education, Culture and Science (Gravity program 024.001.035). ICMS animation studio is acknowledged for the artwork.