Jinlian
Cao‡
a,
Peimin
Weng‡
b,
Yuanwei
Qi
c,
Kexin
Lin
c and
Xiaosheng
Yan
*c
aThe Higher Educational Key Laboratory for Flexible Manufacturing Equipment Integration of Fujian Province, Xiamen Institute of Technology, Xiamen 361021, China
bPeking University Yangtze Delta Institute of Optoelectronics, 226010, Nantong, Jiangsu, China
cFujian Provincial Key Laboratory of Innovative Drug Target Research and State Key Laboratory of Cellular Stress Biology, School of Pharmaceutical Sciences, Xiamen University, Xiamen, Fujian, 361102, China. E-mail: xshyan@xmu.edu.cn
First published on 9th January 2024
An alanine-based bilateral building block, linked by 2,5-thiophenediamide motifs and equipped with C-terminal 4-iodoaniline groups, was designed, allowing a noncovalent interaction network consisting of intramolecular chalcogen bonds and intermolecular halogen/hydrogen bonds, which cooperatively maintain a supramolecular β-sheet organization in the solid state, as well as in dilute CH3CN solution with a high g factor of −0.017.
In this context, we have developed short peptide-based N-amidothioureas, wherein an intramolecular ten-membered ring hydrogen bond can maintain a helical β-turn conformation,14–16 which facilitates intermolecular halogen bonds to allow the formation of single and double supramolecular helices in both the solid state and solution phase.17–19 Intriguingly, the incorporation of a 2,5-thiophenediamide linker into bilateral N-amidothiourea building blocks would afford intramolecular chalcogen bonds, allowing a noncovalent interaction network consisting of intramolecular hydrogen/chalcogen bonds and intermolecular halogen bonds, which leads to a supramolecular helix of stronger supramolecular helicity and higher thermal stability.20 This highlights the cooperative nature of intra- and intermolecular interactions in supporting helical assemblies.
Besides helical structures, β-sheets are another essential biological structure that plays a crucial role in maintaining the conformation and functionality of proteins.21 The development of artificial biomimetic supramolecular β-sheet structures from self-assembling peptides or amino acids is an exciting and promising field with potential applications in materials science and bioengineering.22–24 However, the cooperative effects of intra- and intermolecular interactions in maintaining supramolecular β-sheet structures have yet to be demonstrated, as traditional β-sheet organizations are primarily only supported by intermolecular interactions, e.g. hydrogen bonds.
Herein, we propose to regulate the supramolecular β-sheet organization using intramolecular interactions, achieved by forming a network of intra- and intermolecular noncovalent interactions that work together in a cooperative manner. For this purpose, we designed alanine-based bilateral building block 1 (Scheme 1), which features a 2,5-thiophenediamide linker and 4-iodoaniline groups at both ends. The alanine-based amide bonds can afford intermolecular hydrogen bonds in a β-sheet manner, in considering that unfolded short peptides tend to adopt a β-sheet organization.25,26 Moreover, the 2,5-thiophenediamide motif is known to form intramolecular chalcogen bonds,20 and the terminal iodine atoms can participate in intermolecular halogen bonding.27 These noncovalent interactions facilitate the assembly of the building block 1 by creating an interaction network. Our experiments have confirmed the formation of a biomimetic supramolecular β-sheet structure in both the solid state and dilute CH3CN solution, supported by a noncovalent interaction network consisting of intramolecular chalcogen bonds and intermolecular halogen/hydrogen bonds. The g factor of the assembled structure measures up to −0.017, together with a twisted tape morphology. To further understand the role of specific interactions, we designed control compounds 2, 3 and 4 (Scheme 1), which feature variations in the linker and the absence of terminal iodine atoms. By comparing the structures of the control compounds with that of 1, the significance of intramolecular chalcogen bonds and intermolecular halogen bonds in organizing the β-sheet structure can be illustrated.
Alanine-based bilateral building blocks 1–4 were synthesized following the procedures outlined in Schemes S1–S4 (ESI†). Initially, we measured the absorption and CD spectra of 1–4 in solution. Comparison with 2, 3 and 4 revealed distinct features of 1. Specifically, in dilute CH3CN solution, 1 displayed a red-shifted CD spectrum with significantly stronger Cotton effects at 304 nm and 250 nm. Concomitantly, the absorption spectrum exhibited reduced absorbance and an increased baseline (Fig. 1a). These observations suggest the possible formation of supramolecular chiral assemblies from 1 in CH3CN solution.
Fig. 1 (a) Absorption and CD spectra of 1, 2, 3 and 4 in CH3CN. (b) The g factor profiles of 1, 2, 3 and 4. For clarity, the fluctuated profiles of 2, 3 and 4 at long wavelengths (>305 nm) are omitted (Fig. S1, ESI†). (c) Hydrodynamic diameters of 1, 2, 3 and 4 in CH3CN measured by dynamic light scattering. (d) SEM image of the air-dried sample from CH3CN solution of 1 on a platinum coated silicon wafer. [1] = [2] = [3] = [4] =10 μM. |
The g factor profiles, derived from the absorption and CD spectra (Fig. S1, ESI†),28 disclosed a remarkably high g factor for 1 in CH3CN, particularly at 307 nm, where it reached −0.017 (Fig. 1b). This value is 6, 27 and 34 times higher than that of 2, 3 and 4, respectively. The CD spectra of 1 in CH3CN further demonstrated its pronounced sensitivity to changes of solution temperature, exhibiting a substantial decrease in CD signals upon heating (Fig. S2, ESI†). This observation further supports the hypothesis of supramolecular polymeric species formation from 1 in CH3CN.
Dynamic light scattering (DLS) was next employed, revealing the presence of polymeric species of 1 with diameters approximately 193 nm, while monomers were observed for 2, 3 and 4 in CH3CN (Fig. 1c). SEM images of solution samples of 1 exhibited an ordered tape morphology (Fig. S3, ESI†), characterized by lengths and widths centred at 1.75 μm and 0.22 μm, respectively (Fig. S4, ESI†). Notably, most of the tape structures displayed a twist, specifically right-handed (Fig. 1d and S3, ESI†), indicating the supramolecular helicity of the polymeric species that contributes to the high g factor. Conversely, the SEM images of control compounds 2, 3 and 4 exhibited amorphous blocks (Fig. S5, ESI†).
To gain insight into the structure and formation mechanism of polymeric species of 1 in CH3CN, the molecular conformation and organization were investigated. Two potential conformations have been proposed for alanine-based building block 1 (Fig. 2a).20 In conformation I, the 2,5-thiophenediamide linker enables two intramolecular C–S⋯OC chalcogen bonds, while in conformation II, two intramolecular N–H⋯S–C hydrogen bonds are formed. To determine the conformation of 1, both single crystal structure analysis and 1D/2D NMR were conducted. Crystals suitable for X-ray crystallography were obtained by slowly evaporating a DMF solution of 1. Crystallographic data revealed that molecule 1 crystallized in the triclinic P1 space group, with one molecule in the asymmetric unit (Fig. S6 and Table S1, ESI†). In the crystal, compound 1 adopts cis-form with two intramolecular C–S⋯hOC chalcogen bonds (ChB1 and ChB2) afforded by the 2,5-thiophenediamide linker (Fig. 2b). The distances between S and hO atoms, measured as 3.061 Å (ChB1) and 3.028 Å (ChB2), respectively, are shorter than the sum of the van der Waals radii of O and S atoms (3.320 Å, details on the parameters of noncovalent interactions can be found in Table S2, ESI†). This structure is consistent with the proposed conformation I (Fig. 2a).
The 2D NOESY spectrum of 1, acquired in 60:40 (v/v) CD3CN/DMSO-d6, revealed obvious coupling between the –NHa and –CHc protons (Fig. 2c and Fig. S7, ESI†), indicating the adoption of conformation I of 1 in the solution phase. Temperature-dependent 1H NMR spectra of 1 demonstrated significant changes in the chemical shifts of –NHa and –NHb (−7.21 and −6.51 ppb °C in temperature coefficient, respectively, Fig. S8 and S9, ESI†). These observations suggest that –NHa and –NHb are not involved in intramolecular hydrogen bonding,29 excluding the existence of conformation II of 1 in the solution phase. Consequently, 1 retains conformation I, characterized by two intramolecular C–S⋯hOC chalcogen bonds, both in the solid state and in the solution phase.
The molecular organization of 1 was then investigated by analysing its crystal structure. Along the c-axis of the crystal lattice, the molecules of 1 interact with each other via intermolecular C–I1⋯2I–C halogen bonds (XB1, Table S2, ESI†), effectively forming a chain. Additionally, along the a-axis, these chains align and stack through intermolecular N–Hb⋯iOC hydrogen bonds (HB1 and HB2, Table S2, ESI†). As a result, a halogen- and hydrogen-bonded two-dimensional (2D) structure forms within the ac plane of crystal 1 (Fig. 3a). This 2D structure bears resemblance to the parallel β-sheet structure found in biological systems (Table S3, ESI†),21 where the C–I1⋯2I–C halogen bonds and N–Hb⋯iOC hydrogen bonds serve as intra- and inter-strand interactions, respectively. Furthermore, intramolecular chalcogen bonds (ChB1 and ChB2) contribute to a noncovalent interaction network involving chalcogen/halogen/hydrogen bonds (Fig. S10, ESI†), promoting the stabilization of the biomimetic β-sheet structure.
The 2D biomimetic supramolecular β-sheet structures within the ac plane of crystal 1 further stack in a parallel arrangement along the b-axis, facilitated by intermolecular N–Ha⋯hOC hydrogen bonds (HB3 and HB4) and C–I2⋯1I–C halogen bonds (XB2, Table S2, ESI†), leading to the formation of a three-dimensional (3D) structure (Fig. S11, ESI†). Within the bc plane, halogen bonds (XB1 and XB2) and hydrogen bonds (HB3 and HB4) support a 2D structure that also resembles a β-sheet (Fig. 3b), wherein two halogen bonds propagate along the b-axis alternately, utilizing an iodine atom as both the donor and acceptor (Fig. S12, ESI†). Along the crystallographic a- and b-axes, the centroid–centroid distances of the aromatic rings are measured to be as long as 4.711 Å and 5.189 Å, respectively (Fig. S13, ESI†), suggesting that the contribution of π-stacking to the assembly is negligible.30
Therefore, in the 3D crystal structure, each 1 molecule participates in the formation of two intramolecular C–S⋯OC chalcogen bonds (ChB1 and ChB2), four C–I⋯I–C halogen bonds (XB1 and XB2 doubled), and eight N–H⋯OC hydrogen bonds (HB1, HB2, HB3, and HB4 doubled, Fig. 4a). These interactions together create a strong and resilient noncovalent interaction network that supports the biomimetic β-sheet organization of 1. The Fourier transform infrared spectroscopy (FTIR) of 1 exhibited absorption peaks of the amide I region at 1676 and 1640 cm−1 (Fig. S14, ESI†), indicating the presence of the supramolecular β-sheet structure,31,32 in line with the 3D crystal structure.
Notably, the CD spectrum of 1 in CH3CN solution closely resembles that of the solid state (Fig. 4b), suggesting that 1 adopts a similar assembled structure, i.e. chalcogen, halogen and hydrogen-bonded biomimetic β-sheet organization, in the CH3CN solution and the solid state. The absorption, CD and DLS profiles (Fig. S15, ESI†) indicate that the addition of polar DMSO to the CH3CN solution causes a transition into the monomeric form of 1, which can be attributed to the competition between DMSO and intermolecular halogen and hydrogen bonds.
SEM images of 1 (Fig. 1d and Fig. S3, ESI†) reveal the existence of right-handed twisted tape morphology, which is accountable for the high g factor of 1 in the CH3CN solution. This distinct feature bears a striking resemblance to naturally occurring β-sheets, where β-strands commonly exhibit a right-handed twist.33,34 The crystal structure of 1 reveals that well-oriented hydrogen bonds propagate along the a- and b-axes, while along the c-axis only misaligned halogen bonds drive packing (Fig. 3), which may limit the lateral growth of the supramolecular tapes.
In the case of control compounds 2 and 3, which have a 2,5-furandiamide linker and a terephthalamide linker, respectively, the absence of intramolecular chalcogen bonds prevents the formation of a strong noncovalent interaction network. As a result, 2 and 3 exist in a monomeric form in CH3CN solution (Fig. 1). Control compound 4, which lacks terminal iodine atoms, also adopts a monomeric form in CH3CN due to the absence of intermolecular halogen bonds (Fig. 1). These observations highlight the cooperative nature of chalcogen, halogen and hydrogen bonds in the noncovalent interaction network of 1, which facilitates the formation of the biomimetic β-sheet organization in both the solid state and dilute CH3CN solution.
In summary, we proposed to introduce intramolecular interactions to regulate the formation of a supramolecular β-sheet structure, achieved by forming an intra- and intermolecular noncovalent interaction network. To this end, we designed an alanine-based bilateral building block, linked by a 2,5-thiophenediamide motif and equipped with C-terminal 4-iodoaniline groups. This design allows for the establishment of a noncovalent interaction network that includes intramolecular chalcogen bonds and intermolecular halogen/hydrogen bonds. These interactions work cooperatively to maintain the supramolecular β-sheet structure, not only in the solid state but also in dilute CH3CN solution, resulting in a high supramolecular chirality characterized by a g factor up to −0.017, as well as a twisted tape morphology. The control compounds lacking either intramolecular chalcogen bonds or intermolecular halogen bonds exhibit a loss of assembly behaviour in the CH3CN solution, which emphasizes the importance of the cooperative noncovalent interaction network for the organization of the β-sheet structure. The significance of our findings lies in the potential to aid in the construction and regulation of supramolecular assemblies by incorporating both intra- and intermolecular interactions that can establish a robust noncovalent interaction network to support the assemblies. Ongoing efforts are being made to assess the performance in terms of recognition and transmembrane transport of the assemblies that are supported by synergistic intra- and intermolecular supramolecular interactions.
We are thankful for the support of the NSF of China (22101240, 22241503 and 92356308), Fundamental Research Funds for the Central Universities (20720220121), NSF of Fujian Province of China (2023J01038) and NSF of Xiamen City (3502Z202374089).
Footnotes |
† Electronic supplementary information (ESI) available: CCDC 2304589. For ESI and crystallographic data in CIF or other electronic format see DOI: https://doi.org/10.1039/d3cc05539f |
‡ Equal contribution. |
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