Dichlorobis(DL-proline-κO)zinc(II)

Zn²⁺ ions play an essential role in the regulation and catalytic activity of biological systems (Fraústo da Silva & Williams, 1991). To obtain a deeper insight into the interaction of metal ions with amino acids, neutral salts can be studied. Neutral salts are formed by the interaction of neutral zwitterionic amino acids with metal salts, e.g. CaCl₂, SrCl₂, BaCl₂, and LiCl (Pfeiffer & Wittka, 1915). The crystal structures of neutral salts of Zn²⁺ with DL-penicillamine (Bell & Sheldrick, 1984), D-penicillamine (Bell & Sheldrick, 1984), L-proline (Yukawa et al., 1985), sarcosine (Subha Nandhini et al., 2001), L-t-leucine (Hoffmüller et al., 1999), glycine (Hariharan et al., 1989), DL-valine (Nandhini et al., 2001) and DL-alanine (Subha Nandhini et al., 2002) have already been reported. In all cases, the Zn²⁺ ions are tetrahedrally four-coordinated, with two halogenides and two O atoms of two negatively charged carboxylates as donors. The halogenides act as acceptors of hydrogen bonds, which are donated by the positively charged ammonium groups.

In the structure of dichlorobis(L-proline)zinc(II) (Yukawa et al., 1985), the Zn complex contains two independent L-proline residues. The five-membered ring of one of them has an envelope conformation on C4 and a C—N—C^α—C torsion angle of −0.8 (5)°, while the other has a twist conformation on the C3—C4 bond, with a C—N—C^α—C torsion angle of 11.0 (4)°. From quantum chemical calculations, it is known that the torsion angle of the carboxylate group is correlated with the ring puckering (Ramek et al., 1997). This correlation can also be found in the crystal structures of 83 proline complexes (133 residues) obtained from the Cambridge Structural Database (April 2002 release; Allen, 2002), as shown by a plot of the C—N—C^α—C ring torsion angles versus the N—C^α—C—O torsion angles (Fig. 1). A negative value for the C—N—C^α—C torsion angle results in a positive deviation from 0° for the N—C^α—C—O torsion angle, while a positive value results in a negative deviation. In dichlorobis(L-proline)zinc(II), the N—C^α—C—O torsion angles are −15.2 (5) and 20.9 (5)°, respectively, thus fitting badly into the correlation. The two independent proline residues also differ in the C—O—Zn angles, which are 122.4 (3) and 116.5 (3)°, respectively. For comparison with these data, we prepared the title racemic compound, dichlorobis(DL-proline)zinc(II), (I), and its structure is presented here. \sch

Compound (I) crystallizes in the centrosymmetric spacegroup C2/c. The Zn atom is located on a twofold axis in a distorted tetrahedral environment (Fig. 2). Both proline ligands of one complex consequently have the same absolute configuration, either both R or both S. Conformation analysis of the five-membered ring according to the method of Evans & Boeyens (1989) results in coefficients of 59 and 41% for the envelope and twist conformations, respectively, indicating an intermediate form. The C5—N1—C2—C3 torsion angle is 21.05 (14)° and the O1—C1—C2—N1 torsion angle is −9.81 (16)°, which is perfectly in line with the above-mentioned correlation between these two torsion angles. The C1—O1—Zn1 angle is 128.29 (9)°, which is significantly larger than the corresponding angles in the L-proline complex. As expected, the C1—O1 bond length of the coordinated O atom is significantly longer than C1—O2 of the non-coordinated O atom (Table 1).

Both H atoms of the positively charged ammonium group are involved in hydrogen bonding (Table 2). Atom H1A forms a bifurcated hydrogen bond, with atom O1 of the same proline residue and atom Cl1ⁱ as acceptors [symmetry code: (i) x, 1 + y, z]. The angle sum at H1A is 355 (2)°. Atom H1B forms an intermolecular hydrogen bond to atom O2ⁱ. Due to the hydrogen bonding, a linear chain is formed in the direction of the crystallographic b axis (Fig. 2). Because translation is the only symmetry operation in the generation of these chains, all proline residues within one chain have the same configuration. Of course, in the racemic centrosymmetric crystal, there is the same number of chains with R-proline as with S-proline residues.

Partial separation of chiral molecules in a racemic crystal has been reported before, for the structure of N-acetyl-DL-alanine methylester (Müller & Lutz, 2001), where the hydrogen-bonded chains consist of one R and two S molecules, or vice versa. A complete separation of the R and S forms would lead to a mixture of enantiopure crystals, as in the famous example of sodium ammonium tartrate (Pasteur, 1848). Indeed, we observed this separation in a crystallization experiment, where we obtained a crystalline powder of dichlorobis(L-proline)zinc(II) and dichlorobis(D-proline)zinc(II). The structure of the powder was analyzed by comparison of the measured powder pattern with that calculated from the single-crystal coordinates (Yukawa et al., 1985). This powder was later used as seed crystals for the crystallization of the racemic compound, (I). It seems that, in this case, the conditions of the crystallization experiment control which product is obtained, not the nature of the seed crystals.