1. Chemical context

L-cysteine is an important proteinogenic amino acid widely distributed in living organisms (Lennarz & Lane, 2013). Copper–cysteine clusters are of inter­est as possible models of active sites of some copper-containing proteins (Kretsinger et al., 2013). It is inter­esting to observe that there are no structures of copper complexes with both chloride ions and cysteine and even cystine determined by single crystal X-ray diffraction. As part of our studies in this area, we now describe the synthesis and structure of the title cluster compound.

2. Structural commentary

The crystallographic analysis of the title compound revealed a complex polymeric structure of composition {[Cu₁₆(CysH₂)₆Cl₁₆]·xH₂O}_n, [CysH₂ = HO₂CCH(NH₃⁺)CH₂S⁻]. The copper atoms are linked by thiol­ate groups to form Cu₁₂S₆ copper thiol­ate nanoclusters (`atlas spheres'), which have the form of a tetra­kis cubocta­hedron, made up of a Cu<sub>12</sub> cubo-octa­hedral subunit that is augmented by six sulfur atoms that are located symmetrically atop of each of the Cu<sub>4</sub> square units of the Cu<sub>12</sub> cubo-octa­hedron. The six S atoms form an octa­hedral subunit themselves. The exterior of the Cu<sub>12</sub>S<sub>6</sub> sphere is decorated by chloride ions and trichloro­cuprate units. Three chloride ions are irregularly coordinated to trigonal Cu<sub>3</sub> subunits of the nanocluster, and four trigonal CuCl<sub>3</sub>-units are linked through each of their chloride ions to each one copper ion on the `atlas spheres'. The trigonal CuCl₃ units are covalently connected through Cu₂Cl₂ bridges to equivalent units in neighboring nanoclusters. Four such connections are arranged in a tetra­hedral fashion, forming a diamond like network of Cu₁₂S₆Cl₄(CuCl₃)₄ nanoclusters. The rigid diamond-like network results in large channels occupied by solvate mol­ecules, which in most cases were too poorly defined for modeling. The content of the voids, believed to be water mol­ecules, was accounted using reverse Fourier-transform methods using the SQUEEZE algorithm (Spek, 2015). The protonated amino groups of the cysteine ligands are directed away from the sphere, forming N—H⋯Cl hydrogen bonds with chloride ions of their cluster. The protonated –CO₂H carb­oxy groups point outwards into the void and presumably form O—H⋯O hydrogen bonds with the unresolved water mol­ecules in the solvate channels (the carboxyl­ate protons are omitted in the structure).

Conclusion about the state of the carb­oxy groups is based on the following facts: (i) the FTIR spectrum confirms the presence of –CO₂H groups and the absence of H₃O⁺ ions in the crystal (see below); (ii) the coordination geometries observed are strongly favored by Cu^I; (iii) the crystals of the complex are colorless, which excludes the presence of copper(II).

Disorder is observed in one of the two crystallographically unique [Cu₁₆(CysH₂)₆Cl₁₆] clusters for three of the six cysteine ligands. The asymmetric unit consists of two Cu₁₂ distorted cubo-octa­hedra (Figs. 1, 2). Almost all of the Cu—S bonds are similar in length (mean 2.25 ± 0.03 Å) except for the bonds formed by the disordered S1_1, S1_5 and S1_12 atoms, where the Cu—S bond lengths were determined with higher errors. The S—Cu—S angles are clustered in a narrow range (mean 130 ± 4°). Thus the Cu—S bonds and angles are typical for such Cu₁₂S₆ copper thiol­ate nanoclusters (see Database survey).

Figure 1 Asymmetric unit of the title compound. Orange: copper, yellow: sulfur, green: chlorine, red: oxygen, blue: nitro­gen.

Figure 2 Displacement ellipsoid plot (50% probability level) of the asymmetric unit.

In the `atlas sphere' there are four tetra­hedral copper atoms (atoms Cu17, Cu26, Cu28, Cu32 for the first core and Cu1, Cu9, Cu11, Cu16 for the second) surrounded by two μ₂-chloride ions and one μ₃-chloride ion (for example, Cu1 ion is surrounded by Cl1, Cl2 and Cl3 atoms), which are close to planar with copper and the μ₃-Cl that is almost perpendicular to this imaginary plane wherein the length of Cu—μ₃-Cl bond is longer than the others (mean 2.58 ± 0.04 Å). We note that the lengths of the other Cu—μ₃-Cl bonds are about the same as the Cu—μ₂-Cl lengths (mean 2.31 ± 0.04 Å) and the Cl—Cu—Cl angle in the [Cu₂Cl₂] units is 94.9 ± 2.4°. In addition, there are two non-bridging chloride ions: Cl28 and Cl26. The other chloride ions form μ₂-bridges between the copper ions in the core except for μ₃-Cl15.

The charge distribution per cage is as following: 16 positive charges of Cu⁺ ions are balanced by the negative charges of 16 chloride ions. The 12 amino acid residues occur as neutral CysH₂ = HO₂CCH(NH₃⁺)CH₂S⁻ zwitterions. The `atlas spheres' in the asymmetric unit have differences regarding the presence of disorder, viz. three of the six cysteine mol­ecules are disordered in one `atlas sphere' while the other is not disordered.

3. Supra­molecular features

In the structure, the `atlas spheres' are linked to form a three-dimensional framework with the Cu<sub>2</sub>Cl<sub>2</sub> linkages forming a tetra­hedral environment in each of the clusters (Fig. 3). As a result, the `atlas spheres' form a distorted diamond-like structure (Fig. 4). However, it is not possible to give an exact description of the topology (O'Keeffe et al., 2008). These bridges are based on the μ₃-Cl atoms described above, with the exception of Cl15 and eight copper atoms in a distorted tetra­hedral environment (four such atoms per cage); thus, from the point of view of the coordination environment, it is more accurate to talk about Cu₂Cl₈ bridges. In addition, the cages are connected by a system of hydrogen bonds. Namely, two water mol­ecules (O4_6 and O3_6) act as donors for two amino groups (N1_9 and N1_6, respectively), forming N—H⋯O hydrogen bonds. In turn, the water mol­ecules are linked by hydrogen bonds. Thus, a chain of three hydrogen bonds exists between neighboring `atlas spheres'. The structure has voids in which there are presumably disordered water mol­ecules (Figs. 5, 6). Using PLATON SQUEEZE (Spek, 2015), a void was identified occupying 38.6% of the unit-cell volume for the compound. The void volume of 7685 ų contains the equivalent of 3455 electrons, corresponding to about 346 water mol­ecules. The hydrogen-bond geometry is given in Table 1.

Table 1 Hydrogen-bond geometry (Å, °) D—H⋯A D—H H⋯A D⋯A D—H⋯A N1_1—H1A_1⋯Cl6 0.91 2.73 3.554 (19) 151 N1_1—H1A_1⋯Cl16 0.91 2.66 3.148 (16) 115 N1_1—H1B_1⋯Cl3i 0.91 2.81 3.42 (2) 126 N1A_1—H1AA_1⋯Cl7 0.91 2.74 3.34 (4) 125 N1A_1—H1AA_1⋯Cl9 0.91 2.54 3.28 (3) 138 N1_2—H1A_2⋯Cl4 0.91 2.78 3.395 (15) 126 N1_2—H1A_2⋯O2A_5i 0.91 2.48 3.04 (2) 120 N1_2—H1C_2⋯Cl5 0.91 2.19 3.101 (15) 175 N1_3—H1A_3⋯Cl10 0.91 2.69 3.592 (9) 171 N1_3—H1B_3⋯O2_3 0.91 2.13 2.605 (10) 112 N1_3—H1C_3⋯Cl2 0.91 2.53 3.306 (8) 143 N1_3—H1C_3⋯Cl11 0.91 2.68 3.228 (9) 120 N1_4—H1B_4⋯Cl15 0.91 2.44 3.199 (10) 141 N1_4—H1B_4⋯S1_4 0.91 2.82 3.300 (10) 114 N1_5—H1B_5⋯O2_12 0.91 2.36 3.14 (3) 144 N1_5—H1C_5⋯Cl11 0.91 2.76 3.46 (2) 134 N1_5—H1C_5⋯Cl13 0.91 2.49 3.24 (2) 139 N1A_5—H1A2_5⋯Cl2 0.91 2.74 3.46 (2) 137 N1A_5—H1A2_5⋯Cl11 0.91 2.42 2.99 (2) 121 N1A_5—H1A2_5⋯S1A_5 0.91 2.68 3.22 (4) 119 N1A_5—H1A3_5⋯Cl4ii 0.91 2.82 3.49 (3) 132 N1_6—H1B_6⋯O3_6 0.91 1.92 2.70 (3) 142 N1_6—H1C_6⋯Cl16 0.91 2.53 3.311 (16) 145 N1_6—H1C_6⋯S1_6 0.91 2.89 3.330 (16) 111 N1A_6—H1AC_6⋯Cl11 0.91 2.74 3.60 (7) 158 N1_7—H1B_7⋯Cl23 0.91 2.77 3.435 (9) 131 N1_7—H1B_7⋯Cl26 0.91 2.58 3.315 (9) 138 N1_7—H1C_7⋯O1_13 0.91 1.99 2.803 (12) 148 N1_8—H1C_8⋯Cl26 0.91 2.51 3.370 (12) 158 N1_8—H1C_8⋯S1_8 0.91 2.83 3.286 (13) 112 N1_9—H1A_9⋯Cl20 0.91 2.85 3.585 (9) 139 N1_9—H1A_9⋯O1_10iii 0.91 2.12 2.796 (11) 130 N1_9—H1B_9⋯O4_6 0.91 2.01 2.86 (3) 154 N1_9—H1C_9⋯Cl17 0.91 2.79 3.348 (9) 121 N1_9—H1C_9⋯Cl28 0.91 2.45 3.211 (9) 142 N1_10—H1B_10⋯Cl25 0.91 2.77 3.239 (9) 113 N1_10—H1B_10⋯Cl26 0.91 2.57 3.363 (8) 146 N1_10—H1C_10⋯O2_9iv 0.91 2.15 2.856 (12) 134 N1_11—H1A_11⋯O1_13v 0.91 2.08 2.971 (13) 167 N1_11—H1C_11⋯Cl21 0.91 2.61 3.362 (10) 141 N1_11—H1C_11⋯Cl24 0.91 2.61 3.235 (9) 126 N1_12—H1A_12⋯Cl31 0.91 2.92 3.387 (9) 113 N1_12—H1C_12⋯Cl29 0.91 2.44 3.316 (9) 161 O4_6—H4B_6⋯Cl12 0.84 (1) 2.89 (10) 3.32 (3) 114 (8) O4_6—H4B_6⋯O3_6 0.84 (1) 1.76 (7) 2.51 (4) 148 (10) O1_13—H1A_13⋯Cl25 0.82 (3) 2.97 (3) 3.501 (9) 125 (2) Symmetry codes: (i) ; (ii) ; (iii) ; (iv) ; (v) .

Figure 3 Tetra­hedral environment of `atlas-sphere' of the title compound.

Figure 4 Diamond-like extended structure of the title compound.

Figure 5 Crystal packing of the title compound viewed along c-axis direction.

Figure 6 Visualization of the void space of the title compound viewed along the b-axis direction.

4. Database survey

Considering copper(I) complexes with cysteine, a number of heteroligand Co^III/Cu^I complexes with ethyl­enedi­amine are known where the inner sphere of Co^III contains two coord­in­ated ethyl­enedi­amine mol­ecules and one monoprotonated L-cysteine mol­ecule coordinated via nitro­gen and sulfur ([Co(en)₂(L-CysH)]). In addition, the sulfur atom of cysteine is coordinated to the Cu^I atom, which is surrounded by other sulfur atoms and chloride ions ([CuCl₃S], [CuClS₃], [CuClS₂]), for example, see Cambridge Structural Database (CSD; Groom et al., 2016) refcodes TOHREO, XOMDEJ, XOMDIN, XOMDOT, XOMDUZ, XOMFAH (Aridomi et al., 2008). A copper(II) complex with S-methyl-L-cysteine of composition [Cu(L-MeCys)₂]_n (MeCysH = HO₂CCH(NH₂)CH₂SCH₃) has been characterized (Dubler et al., 1986). The ligand coordin­ates to the metal ion via its oxygen and nitro­gen atoms and the structure is polymeric because both carb­oxy­lic groups are also coordinated to other copper(II) atoms. It should be noted that only one copper(II)–cystine complex has been synthesized, which includes 2,2′-bipyridyl as a second ligand (Seko et al., 2010).

Several copper–cyste­amine (CyH = ⁻SCH₂CH₂NH₃⁺) structures have been reported: {[Cu₈Cl₆(CyH)₆]Cl₂}_n (Salehi et al., 1997); [Cu₁₃Cl₁₃(CyH)₆·H₂O]_n consisting of [Cu₁₂S₆Cl₁₂] clusters bridged by Cl and [Cu₂Cl₂] units (Parish et al., 1997); {[Cu₁₃(CyH)₆Br₁₃]·xH₂O}_n formed of [Cu₁₂(CyH)₆Br₁₂] clusters, which are linked by [Cu₂Br₂] bridges (Prichard et al., 1999), and the most recent one [Cu₃Cl(Cy)₂] (here cyste­amine has deprotonated amino and thio groups) where there are parallel chains [Cu₂Cy₂]_n connected to neighboring ones by [CuCl] links (Ma et al., 2014). In addition, there are five complexes of copper(I) with cystamine (H₂NCH₂CH₂S–SCH₂CH₂NH₂) and bromide ligands (Louvain et al., 2008). The dimethyl derivative of cyste­amine forms a complex {[Cu₁₇(RS)₆Cl₁₇]}_n [RS = ⁻SCH₂CH₂NH(CH₃)₂⁺] including a [Cu₁₂S₆] cluster (Prichard et al., 1999). In addition, the [Cu₆S₁₂] cluster has been found in copper–thiol systems: [Cu₁₂(SR′)₆Cl₁₂][(Cu(R′SH))₆] (R′ = n-Bu) and [H(THF)₂]₂[Cu₁₇(SR′′)₆Cl₁₃(THF)₂(R′′SH)₃] (R′′ = CH₂CH₂Ph) (Cook et al., 2019).

Thus [Cu₁₂S₆] clusters in copper(I) complexes with cyste­amine, a close derivative of cysteine, are stabilized with Cl⁻ or Br⁻ anions. Chloride ions also stabilize such clusters containing simple thiols. It should be noted that phosphine ligands also can stabilize a [Cu₁₂S₆] core containing just sulfur instead of thiols and forming [Cu₁₂S₆(PR₃)₈] complexes: [Cu₁₂S₆(PPh₂Et)₈], [Cu₁₂S₆(PEt₃)₈] (Dehnen et al., 1994) and [Cu₁₂S₆(P_nPR₃)₈] (Dehnen et al., 1996). Moreover, there are some complexes containing four diphosphine ligands (Eichhöfer et al., 2015, Yang et al., 2014, Khadka et al., 2013) with high photoluminescence quantum yields.

5. Synthesis and crystallization

Masses of 0.085 g (0.500 mmol) of CuCl₂·2H₂O and 0.060 g (0.50 mmol) of L-cysteine were mixed in 5 ml of water under inert conditions. A precipitate was formed, which was dissolved by adding approximately 1 ml of a 2 M HCl oxygen-free solution. The resulting solution was left to stand in an inert atmosphere. Colorless crystals of the title compound formed within 24 h.

As a result of the rapid degradation of the crystals in air, it was not possible to perform an elemental analysis. The IR spectra of the crystals were recorded using an FTIR Bruker Vertex 70 spectrometer (400–4000 cm⁻¹). The IR spectrum of {[Cu₁₆(CysH₂)₆Cl₁₆]·xH₂O}_n (1) is shown in Fig. 7, and the spectroscopic parameters are presented in Table 2 in comparison with the corresponding values for the crystal of L-cysteine hydro­chloride, L-CysH₂·HCl (Dokken et al., 2009) along with our assignment of the spectroscopic lines.

Figure 7 IR spectrum of the title compound.

As follows from Table 2, there is a satisfactory correspondence of most bands of both crystals, 1 and L-CysH₂·HCl. Of particular note is the almost complete coincidence of the position of the most intense line at 1201–1203 cm⁻¹ for both compounds. According to Dokken et al. (2009), this intense band is associated with vibrations of the protonated –COOH group. In this case, the possibility of protonation of water mol­ecules instead of a carb­oxy group with the hydroxonium ion formation is practically excluded. Indeed, according to numerous experimental and calculated data for crystals and liquid phases, H₃O⁺ ions show four broad lines in the IR spectra near 1150, 1740, 3160, and 3320 cm⁻¹ (Chukanov, 2014; Yukhnevich, 1973). As follows from Fig. 7 and Table 2, no sign of these bands was detected in the spectrum of the crystal 1. On the other hand, there is a satisfactory agreement between the vibration lines of the –NH₃⁺ group at ∼1130, ∼1572, ∼1610, and ∼2930 cm⁻¹ for compounds 1 and L-CysH₂·HCl. Thus, according to the IR spectroscopic data, the protons in 1 are localized on the carboxyl and ammonium groups, while the thiol groups are deprotonated and bonded to copper(I).

6. Refinement

Crystal data, data collection and structure refinement details are summarized in Table 3. All non-hydrogen atoms were refined anisotropically and C—H hydrogen atoms were positioned at geometrically calculated positions (C—H = 0.99–1.00 Å, N—H = 0.91 Å) and refined using a riding model. The constraint U_iso(H) = 1.2U_eq(C) or 1.5U_eq(N) was applied in all cases. Three of the cysteine ligands were found to be disordered over two sets of sites with refined major occupancies of 0.826 (8), 0.550 (19) and 0.657 (9). Close to one of the disordered cysteine ligands, two partially occupied water mol­ecules were found, which could not be modeled using SQUEEZE (Spek, 2015) because of their proximity to the cysteine disorder. Their occupancy was refined freely and converged to 0.55 (2) and 0.33 (2). The structure was refined with the help of similarity restraints, strong similarity restraints on anisotropic displacement parameters (Müller, 2009) and rigid bond restraints (Thorn et al., 2012) on the disordered ligands. One of the partially occupied water mol­ecules was strongly restrained to have a more isotropic behavior using the ISOR instruction as implemented in SHELXL. The unit cell contains a significant amount of solvent, most likely a heavily disordered hydrogen-bonded network of water mol­ecules. To refine the model against the measured data, the SWAT instruction as implemented in SHELXL (Langridge et al., 1960; Driessen et al., 1989) was used. In addition, SQUEEZE (Spek, 2015) as implemented in PLATON (Spek, 2020) was used to model the disordered solvent in the voids of the structure. SQUEEZE identified a void centered at ∼(0 0.1 0) with a volume of 7685 ų containing the equivalent of 3455 electrons. This would correspond to about 346 water mol­ecules.

Table 3 Experimental details Crystal data Chemical formula [Cu32Cl32(C3H6NO2S)12]·2.68H1.97O Mr 4643.74 Crystal system, space group Monoclinic, C2 Temperature (K) 100 a, b, c (Å) 29.4665 (14), 22.1299 (11), 28.9371 (14) β (°) 97.3964 (14) V (Å3) 18712.6 (16) Z 4 Radiation type Mo Kα μ (mm−1) 4.18 Crystal size (mm) 0.36 × 0.31 × 0.13   Data collection Diffractometer Bruker PHOTON100 Absorption correction Multi-scan (SADABS; Sheldrick, 2016) Tmin, Tmax 0.487, 0.746 No. of measured, independent and observed [I > 2σ(I)] reflections 189540, 33050, 26149 Rint 0.050 (sin θ/λ)max (Å−1) 0.595   Refinement R[F2 > 2σ(F2)], wR(F2), S 0.041, 0.114, 1.09 No. of reflections 33050 No. of parameters 1568 No. of restraints 1778 H-atom treatment H atoms treated by a mixture of independent and constrained refinement Δρmax, Δρmin (e Å−3) 0.56, −0.74 Absolute structure Flack x determined using 10959 quotients [(I+)−(I−)]/[(I+)+(I−)] (Parsons et al., 2013) Absolute structure parameter 0.030 (4) Computer programs: APEX3 and SAINT (Bruker, 2017), SHELXT2015 (Sheldrick, 2015a), SHELXL2018/3 (Sheldrick, 2015b) and SHELXTL (Sheldrick, 2008).