Design, synthesis and high antitumor potential of new unsymmetrical bisacridine derivatives towards human solid tumors, specifically pancreatic cancers and their unique ability to stabilize DNA G-quadruplexes.

New promising unsymmetrical bisacridine derivatives (UAs), have been developed. Three groups including 36 compounds were synthesized by the condensation of 4-nitro or 4-methylacridinone, imidazoacridinone and triazoloacridinone derivatives with 1-nitroacridine compounds linked with an aminoalkyl chain. Cytotoxicity screening revealed the high potency of these compounds against several tumor cell lines. Particularly, imidazoacridinone-1-nitroacridine dimers strongly inhibited pancreatic Panc-1, Mia-Pa-Ca-2, Capan-2 and prostate cancer DU-145 cell growth. The studied compounds showed very strong antitumor activity (T/C> 300%) against Walker 256 rat adenocarcinoma. The selected 26 UAs were tested against 12 human tumor xenografts in nude mice, including colon, breast, prostate and pancreatic cancers. The studies on the molecular mechanism of action demonstrated that these unsymmetrical dimers significantly responded to the presence of G-quadruplex not to dsDNA. Structure-activity relationships for UAs potency to G-quadruplex stabilization indicated that thermal stability of this drug-G-quadruplex complex depended not only on the structure of heterocyclic rings, but also on the properties of dialkylamino chains of the ring linkers. In conclusion, the presented studies identified the new group of effective antitumor agents against solid human tumors, particularly pancreatic Panc-1, BxPC-3 and Mia-Pa-Ca-2 and strongly indicated their distinctive interactions with DNA. In contrast to monomers, G-quadruplex not dsDNA is proposed to be the first molecular target for these compounds.

DNA-damaging imidazoacridinone C-1311 induces autophagy followed by irreversible growth arrest and senescence in human lung cancer cells.

Imidazoacridinone 5-diethylaminoethylamino-8-hydroxyimidazoacridinone (C-1311) is an antitumor inhibitor of topoisomerase II and FMS-like tyrosine kinase 3 receptor. In this study, we describe the unique sequence of cellular responses to C-1311 in human non-small cell lung cancer (NSCLC) cell lines, A549 and H460. In A549 cells, C-1311 (IC80 = 0.08 µM) induced G1 and G2/M arrests, whereas H460 cells (IC80 = 0.051 µM) accumulated predominantly in the G1 phase. In both cell lines, cell cycle arrest was initiated by overexpression of p53 but was sustained for an extended time by elevated levels of p21. Despite prolonged drug exposure (up to 192 hours), no apoptotic response was detected in either cell line. Instead, cells developed a senescent phenotype and did not resume proliferation even after 2 weeks of post-treatment, indicating that C-1311-triggered senescence was permanent. When cell cycle arrest was evident but there were no signs of senescence, C-1311 significantly induced autophagic cells. Pharmacological inhibition of autophagy by 3-methyladenine profoundly reduced the senescent phenotype and slightly sensitized cancer cells to C-1311 by increasing cell death, suggesting a link between both autophagy and senescence. However, a small interfering RNA-mediated knockdown of the autophagy-associated Beclin 1 and ATG5 genes attenuated but failed to block development of senescence. Taken together, our studies suggest that in NSCLC, a C-1311-induced senescence program is preceded and corroborated but not exclusively determined by the induction of autophagy.

Diminished toxicity of C-1748, 4-methyl-9-hydroxyethylamino-1-nitroacridine, compared with its demethyl analog, C-857, corresponds to its resistance to metabolism in HepG2 cells.

The narrow "therapeutic window" of anti-tumour therapy may be the result of drug metabolism leading to the activation or detoxification of antitumour agents. The aim of this work is to examine (i) whether the diminished toxicity of a potent antitumour drug, C-1748, 9-(2'-hydroxyethylamino)-4-methyl-1-nitroacridine, compared with its 4-demethyl analogue, C-857, results from the differences between the metabolic pathways for the two compounds and (ii) the impact of reducing and/or hypoxic conditions on studied metabolism. We investigated the metabolites of C-1748 and C-857 formed in rat and human liver microsomes, with human P450 reductase (POR) and in HepG2 cells under normoxia and hypoxia. The elimination rate of C-1748 from POR knockout mice (HRN) was also evaluated. Three products, 1-amino-9-hydroxyethylaminoacridine, 1-aminoacridinone and a compound with an additional 6-membered ring, were identified for C-1748 and C-857 in all studied metabolic systems. The new metabolite was found in HepG2 cells. We showed that metabolic rate and the reactivity of metabolites of C-1748 were considerably lower than those of C-857, in all investigated metabolic models. Compared with metabolism under normoxia, cellular metabolism under hypoxia led to higher levels of 1-aminoacridine and aza-acridine derivatives of both compounds and of the 6-membered ring metabolite of C-1748. In conclusion, the crucial role of hypoxic conditions and the direct involvement of POR in the metabolism of both compounds were demonstrated. Compared with C-857, the low reactivity of C-1748 and the stability of its metabolites are postulated to contribute significantly to the diminished toxicity of this compound observed in animals.

Anticancer imidazoacridinone C-1311 inhibits hypoxia-inducible factor-1α (HIF-1α), vascular endothelial growth factor (VEGF) and angiogenesis.

Antitumor imidazoacridinone C-1311 is a DNA-reactive topoisomerase II and FLT3 receptor tyrosine kinase inhibitor. Here, we demonstrate the mechanism of C-1311 inhibitory action on novel targets: hypoxia-inducible factor-1α (HIF-1α), vascular-endothelial growth factor (VEGF), and angiogenesis. In a cell-free system, C-1311 prevented HIF-1α binding to an oligonucleotide encompassing a canonical hypoxia-responsive element (HRE), but did not directly interfere with HIF-1α protein. Whereas C-1311 did not affect HIF-1α transcription, at higher concentrations (10 µM), it decreased HIF-1α protein accumulation. Furthermore, C-1311 potently reduced the transcription of HIF-1-dependent reporter gene as well as endogenous HIF-1 target gene encoding vascular endothelial growth factor. In colon cancer HCT116 and murine melanoma B16/F10 cells, C-1311-induced down-regulation of VEGF, resulted in decreased VEGF protein expression. C-1311 did not alter normoxic VEGF secretion. Consistent with VEGF depletion, C-1311 significantly affected angiogenesis in vivo. A single dose of C-1311 (40 mg/kg), inhibited angiogenesis by 70%, as measured by vascularization of Matrigel plugs in mice. Continuous low C-1311 dosing (8 mg/kg/day for 5 days) gave similar inhibition of angiogenesis (80%), suggesting that low-dose, frequent C-1311 administration may be more effective in terms of reducing toxicity. Anti-angiogenic activity of C-1311 was further demonstrated in an experimental model in which B16/F10 cells were encapsulated in alginate beads and implanted into mice. C-1311 (8 mg/kg/day for 9 days), completely abrogated vascularization of the alginate implants. Our findings indicate that C-1311 is an effective inhibitor of HIF-1α, VEGF, and angiogenesis and provide new perspectives into the mechanism of its anticancer activity.

Antitumor 1-nitroacridine derivative C-1748, induces apoptosis, necrosis or senescence in human colon carcinoma HCT8 and HT29 cells.

C-1748 is a DNA-binding agent with potent antitumor activity, especially towards prostate and colon carcinoma xenografts in mice. Here, we elucidated the nature of cellular response of human colon carcinoma HCT8 and HT29 cells to C-1748 treatment, at biologically relevant concentrations (EC(90) and their multiplicity). Cell cycle analysis showed gradual increase in HCT8 cells with sub-G1 DNA content (25% after 72h) considered as apoptotic. Hypodiploid cell population increased up to 60% upon treatment with 4x EC(90) concentration of the drug. Compared with HCT8 cells, the fraction of sub-G1 HT29 cells did not exceed 14%, even following 4-fold dose escalation. Morphological changes and biochemical markers such as: phosphatydylserine externalization, apoptotic DNA breaks, mitochondrial dysfunction and caspase activation confirmed the presence of considerable amount of apoptotic HCT8 cells but only a low amount of apoptotic HT29 cells. Next, we demonstrated that HCT8 cells surviving after exposure to C-1748 were in the state of senescence, based on altered cell morphology and expression of a pH 6-dependent beta-galactosidase. On the contrary, no beta-galactosidase staining was observed in HT29 cells after C-1748 treatment. Moreover, prolonged drug incubation (up to 168h) resulted in massive detachment of cells from culture plates, which together with Annexin V/PI results, indicated that necrosis was the main response of HT29 cells to C-1748 treatment. We also determined the ability of C-1748 to induce reactive oxygen species (ROS) in colon cancer cells and demonstrated, that generation of ROS was not essential for C-1748-induced apoptosis and cytotoxic activity of this drug.

Limitation of usage of PicoGreen dye in quantitative assays of double-stranded DNA in the presence of intercalating compounds.

PicoGreen is a very sensitive fluorescent dye for quantitative assays of double-stranded DNA (dsDNA) in solution and is used in several analytical protocols in which sensitive and precise DNA detection is needed, also for examination of drug-DNA interactions. The data shown in this paper indicate that compounds intercalating to DNA influence the applicability of PicoGreen dye for quantitative measurements of dsDNA, and for this reason PicoGreen dye is not suitable for examination of drug-DNA interactions, especially interstrand DNA crosslinks.

Metabolic transformations of antitumor imidazoacridinone, C-1311, with microsomal fractions of rat and human liver.

The imidazoacridinone derivative C-1311 is an antitumor agent in Phase II clinical trials. The molecular mechanism of enzymatic oxidation of this compound in a peroxidase model system was reported earlier. The present studies were performed to elucidate the role of rat and human liver enzymes in metabolic transformations of this drug. C-1311 was incubated with different fractions of liver cells and the reaction mixtures were analyzed by RP-HPLC. We showed that the drug was more sensitive to metabolism with microsomes than with cytosol or S9 fraction of rat liver cells. Incubation of C-1311 with microsomes revealed the presence of four metabolites. Their structures were identified as dealkylation product, M0, as well as a dimer-like molecule, M1. Furthermore, we speculate that the hydroxyl group was most likely substituted in metabolite M3. It is of note that a higher rate of transformation was observed for rat than for human microsomes. However, the differences in metabolite amounts were specific for each metabolite. The reactivity of C-1311 with rat microsomes overexpressing P450 isoenzymes, of CYP3A and CYP4A families was higher than that with CYP1A and CYP2B. Moreover, the M1 metabolite was selectively formed with CYP3A, whereas M3 with CYP4A. In conclusion, this study revealed that C-1311 varied in susceptibility to metabolic transformation in rat and human cells and showed selectivity in the metabolism with P450 isoenzymes. The obtained results could be useful for preparing the schedule of individual directed therapy with C-1311 in future patients.

Sequential induction of mitotic catastrophe followed by apoptosis in human leukemia MOLT4 cells by imidazoacridinone C-1311.

Imidazoacridinone C-1311 is a DNA-targeting antitumor intercalator/alkylator currently undergoing Phase II clinical trials. Here, we elucidated the sequence of death responses to C-1311 in human leukemia MOLT4 cells using drug concentration (30 nM) that causes near complete cell growth inhibition at 48 h. Early (6-12 h) responses included transient accumulation of cells at the G2/M border followed by also transient rise in several mitotic markers. Mitotic attempts were largely abnormal, resulting in numerous multinucleated cells (peaking at 24-39 h and declining markedly at later times). These events, indicative of mitotic catastrophe, were not associated with immediate cell death. The fraction of necrotic cells did not exceed 3%. Also, the classical manifestations of apoptosis were marginal at 24 h and their progression clearly followed the decline in the fraction of mitotic and multinucleated cells. Quantification of several apoptotic markers (including phosphatidylserine externalization, apoptotic DNA breaks, mitochondrial dysfunction, caspase activation, and cell membrane integrity) showed a considerable progression and the shift from early to late apoptosis at later times. At 72 h, >80% of cells were apoptotic. Collectively, these findings show that C-1311-induced mitotic catastrophe is not the ultimate death event but rather a step precipitating delayed, albeit massive, apoptotic responses.

Pre-clinical evaluation of 1-nitroacridine derived chemotherapeutic agent that has preferential cytotoxic activity towards prostate cancer.

Chemotherapy in prostate cancer (CaP) even as an adjunct has not been a success. In this communication, we report the pre-clinical efficacy of a nitroacridine derivative, C-1748 (9[2'-hydroxyethylamino]-4-methyl-1-nitroacridine) in CaP cell culture and human xenograft animal models. C-1748, a DNA intercalating agent has been derived from its precursor C-857 that was a potent anti-cancer drug, but failed clinical development due to "high" systemic toxicities. Chemical modifications such as the introduction of a "methyl" group imparted novel properties, the most interesting of which is the difference in the IC(50) values between LnCaP (22.5 nM), a CaP cell line and HL-60, a leukemia cell line (>100 nM). Using gammaH2AX as an intervention marker of DNA double strand breaks, we concluded that C-1748 is more efficacious in CaP cells than in HL-60 cells. In hormone dependent cells, the androgen receptor (AR) was identified as an additional target of C-1748. In xenograft studies, administration of C-1748 intra-peritoneally inhibited tumor growth by 80-90% with minimal toxicity. These studies identify C-1748 as a novel acridine drug that has a high therapeutic index and low cytotoxicity on myelocytic cells with potential for clinical development.

Interactions of antitumor triazoloacridinones with DNA.

Triazoloacridinones (TA) are a new group of potent antitumor compounds, from which the most active derivative, C-1305, has been selected for extended preclinical trials. This study investigated the mechanism of TA binding to DNA. Initially, for selected six TA derivatives differing in chemical structures as well as cytotoxicity and antitumor activity, the capability of noncovalent DNA binding was analyzed. We showed that all triazoloacridinones studied stabilized the DNA duplex at a low-concentration buffer but not at a salt concentration corresponding to that in cells. DNA viscometric studies suggested that intercalation to DNA did not play a major role in the mechanism of the cytotoxic action of TA. Studies involving cultured cells revealed that triazoloacridinone C-1305 after previous metabolic activation induced the formation of interstrand crosslinks in DNA of some tumor and fibroblast cells in a dose dependent manner. However, the detection of crosslink formation was possible only when the activity of topoisomerase II in cells was lowered. Furthermore, it was impossible to validate the relevance of the ability to crosslink DNA to biological activity of TA derivatives.

Preclinical toxicological examination of a putative prostate cancer-specific 4-methyl-1-nitroacridine derivative in rodents.

Nitroacridines are potent DNA-binding and cytotoxic agents in cancer cells, but could not be developed clinically due to high systemic toxicities. We are developing a 1-nitroacridine derivative, 9-(2'-hydroxyethylamino)-4-methyl-1-nitroacridine (C-1748), as an effective chemotherapeutic agent for prostate cancer. C-1748 demonstrates high antitumor efficacy against human prostate cancer xenografts with markedly low mutagenicity and toxicity in dogs compared with its parent 9-(2'-hydroxyethylamino)-1-nitroacridine (C-857). A surprising feature of C-1748 is the 40-fold difference in 50% inhibitory concentration between DU145 prostate cancer and HL-60 leukemia cells. In this study, we report the preclinical toxicity study of a single acute dose of C-1748 in Copenhagen rats and BALB/c mice, intraperitoneally and intravenously for 24 h and 7 days. The effect of C-1748 on hematology, cardiac and liver enzymes, and renal electrolytes was assessed by blood and serum analysis. The LD50 (lethal dose, 50%) for C-1748 was 9 and 13.42 mg/kg compared with 2.2 and 3 mg/kg for C-857 intraperitoneally and intravenously, respectively, in mice. In Copenhagen rats, LD50 was 15 and 14.4 mg/kg intraperitoneally and intravenously, respectively, compared to 4 and 1.3 mg/kg for C-857. No changes in blood cell counts were observed, which were in the normal range for rodents. No changes were observed in clinical chemistries of enzymes such as aspartate aminotransferase, alkaline phosphatase and creatine phosphokinase, which were within the normal range of values. No genome alterations were seen in prostate cancer cell lines by comparative genomic hybridization together with a lack of systemic toxicity, making it a unique cancer cell-type-specific drug that needs further clinical evaluation for toxicity and synergy in combination chemotherapy regimens.

Induction of G2/M phase arrest and apoptosis of human leukemia cells by potent antitumor triazoloacridinone C-1305.

In this study, we show that triazoloacridinone derivative C-1305, a potent antitumor compound, in human lymphoblastic (MOLT4) and promyelocytic (HL60) leukemia cells induces G2/M arrest followed by apoptosis. In both type of cells, C-1305 at biological relevant concentrations corresponding to EC(90) value, induced a significant increase in the fraction of G2/M cells. The cell cycle perturbations were accompanied by the appearance of sub-G1 fraction, which can be considered as the apoptotic cells population. In both human leukemia cells apoptosis was additionally proved by appearance of DNA fragmentation, activation of caspase-3, PARP cleavage, externalization of phosphatydilserine as well as decrease of the mitochondrial transmembrane potential DeltaPsi(m) and ATP depletion. Treatment of lymphoblastic MOLT4 cells with the C-1305 at EC(90) concentration, caused massive death by apoptosis. Compared to MOLT4 cells, the capacity of HL60 cells to execute apoptosis after C-1305 treatment at equitoxic dose was significantly weaker, but very effective at high concentration (4x EC(90)). These differences could originate from different sensitivity of both cell types to cytotoxic action of C-1305 (EC(50) value for MOLT4 cells was 8 times lower than for HL60 cells and the EC(90) value was 14 times lower, respectively). Collectively, these results show that C-1305 is a novel and potent compound which induces G2/M arrest and subsequent apoptosis of human leukemia cells. This strong ability to induce apoptosis of tumor cells support the view that C-1305 could be consider as a new potent and promising antitumor agent.

[Actinomycin D and its mechanisms of action]. / Aktynomycyna D i mechanizmy jej dzialania.

Actinomycin D is a well-known antibiotic of the actinomycin group that exhibits high antibacterial and antitumor activity. Actinomycin D has been widely used in clinical practice since 1954 as an anticancer drug for treating many tumors and it is also a useful tool in biochemistry and molecular biology. According to the Internet bibliographic database -- MEDLINE, actinomycins, and mainly actinomycin D, have been the subject of about 3300 science papers so far, and this paper is a review of the information concerning the mechanisms of action of actinomycin D. There are several mechanisms of its action that are responsible for its cytotoxic and antitumor action, these being associated with DNA functionality, leading to RNA and, consequently, protein synthesis inhibition. The two main mechanisms are intercalation to DNA and the stabilization of cleavable complexes of topoisomerases I and II with DNA, in which a phenoxazone ring localizes between GpC base pair sequence in DNA and polypeptide lactones rings occupy a position in the minor groove of the DNA helix or the drug penetrates to a place in the DNA structure where topoisomerase binds with DNA, respectively. Moreover, the slow dissociation of actinomycin D from DNA complexes, its photodynamic activity and free radical formation, as well as other biochemical effects of activity of actinomycin D may be, as suggested, important factors that influence the biological activity of this drug. In the literature not enough convincing evidence has been proposed that could indicate one particular mechanism of action as responsible for the biological activity of actinomycin D.

Antitumour imidazoacridone C-1311 induces cell death by mitotic catastrophe in human colon carcinoma cells.

In this study, we investigated the cell death process induced by imidazoacridone C-1311 (Symadex) in HT-29 human colon carcinoma cells which have been shown to be preferentially sensitive to this compound in experimental tumour models both in vitro and in nude mice. Compound C-1311 at the EC(99) dose delayed progression of cells through the S phase which was followed by G2 arrest. At 48-96 h after drug exposure, an increasing fraction of cells rounded up and detached from the substratum which suggested the induction of cell death. This was confirmed by the induction of DNA fragmentation as revealed by pulse field electrophoresis and DNA strand breaks by the TUNEL assay. The dying cells had also mitotic features which were evidenced by various biochemical and morphological criteria such as activation of Cdk1 kinase, presence of the mitotic epitope MPM-2 and condensation of chromatin into mitotic chromosomes in drug-treated cells. These results show that C-1311 does not induce rapid apoptosis in HT-29 cells, instead drug exposure leads to prolonged G2 arrest followed by G2 to M transit and cell death during mitosis in the process of mitotic catastrophe.

Molecular mechanism of the enzymatic oxidation investigated for imidazoacridinone antitumor drug, C-1311.

The imidazoacridinone derivative, C-1311, is an antitumor agent that has been under phase I of clinical trial. The work presented here aims to elucidate the molecular mechanism of the enzymatic oxidative activation of this drug in such a model metabolic system, where the covalent binding to DNA was previously demonstrated. The oxidative activation of C-1311 was performed with HRP/H(2)O(2) and MPO/H(2)O(2) systems. The obtained final products of such transformations were separated and analysed by HPLC. The structures of the products were identified by means of ESI-MS and NMR. It was demonstrated that C-1311 was oxidised with HRP and MPO in the manner dependent on the drug:H(2)O(2) ratio and the drug was more susceptible to HRP oxidation than to MPO. Structural studies showed compounds C0 and C1 to be the result of dealkylation, which occurred in the amino groups of the side chain. The structures of C3 and C4 products were identified as dimers, whose monomers held the imidazoacridinone core. The activation of the imidazoacridinone ring system in position ortho to 8-hydroxyl group was necessary to form such dimers. We suggest that similar mechanism of C-1311 activation should occur in the presence of DNA when, instead of the dimer formation, the covalent binding to DNA, showed earlier for this drug, was formed. Since peroxidase-type enzymes are present in the cell nucleus of tumour cells the activation mechanisms of the C-1311 proposed here may be expected to take place in the cellular environment in vivo.

Intercalation of imidazoacridinones to DNA and its relevance to cytotoxic and antitumor activity.

Imidazoacridinones (IA) are a class of antitumor agents which includes C-1311, an interesting drug in clinical trials. This study investigated the mechanism of IA binding to DNA for a series of 13 analogs that differ in their cytotoxic potency. Using C-1311 as a model compound, crystallographic, spectroscopic and biochemical techniques were employed to characterize drug-DNA interactions. X-ray crystallographic analysis revealed a planar structure of imidazoacridinone core that is capable of intercalative DNA binding. Accordingly, C-1311 binding to DNA followed 'classical' pattern observed for intercalation, as proved by the DNA topoisomerase I-unwinding experiments, with relatively weak binding affinity (K(i)=1.2 x 10(5)M(-1)), and the binding site size of 2.4 bp. Other IA also bound to DNA with the binding affinity in the range of 10(5)M(-1) and binding site size of 2-3 bp, suggesting a prevalence of the intercalative mechanism, similar to C-1311. Considerable DNA binding affinity was displayed by all the highly cytotoxic derivatives. However, none of the analyzed drug-DNA binding parameters was significantly correlated with IA biological activities such as cell growth, DNA and RNA synthesis inhibition, or tumor growth inhibition, which suggests that the IA ability to non-covalently bind to DNA is not crucial for their biological activity. These results show that the ability to intercalate into DNA is a prominent attribute of IA, although factors other than intercalative binding seem to be required for the biological activities of IA drugs.

Coordination and peri-Carbon Metalation of 1-Nitro-9-[(2-aminoethyl)amino]acridines toward Platinum(II). Evidences for Hydrogen Bonding between Endocyclic N(10)H and Chloride Ion.

The antitumor drugs 1-nitro-9-[(2-(dialkylamino)ethyl)amino]acridines (alkyl = Me, A(1); Et, A(2)) with platinum(II) give tridentate coordination compounds in which the two nitrogens of the ethylenediamine side chain and the C(8) carbon atom of the acridine ring system act as donor atoms. An excess of triphenylphosphine displaces the residual chloride coordinated to platinum but leaves unaltered the tridentate acridine ligand. The structures of [Pt(A(1)-H)Cl], 1, and [Pt(A(1)-H)(PPh(3))]Cl, 3, have been solved by single-crystal X-ray diffraction. 1.CHCl(3) crystallizes in the orthorhombic system, space group P2(1)2(1)2(1) (no. 19), with a = 8.715(1) Å, b = 11.045(2) Å, c = 22.609(4) Å, Z = 4, R = 0.0559, and R(w) = 0.0561 for 1502 reflections with F > 3sigma(F). 3.(1)/(2)CH(2)Cl(2) crystallizes in the monoclinic system, space group P2(1)/c (no. 14), with a = 13.418(3) Å, b = 14.053(3) Å, c = 18.918(4) Å, beta = 97.21(3) degrees, Z = 4, R = 0.0591, and R(w) = 0.0611 for 3608 reflections with F > 4sigma(F). In both complexes the acridine ligand adopts an imino-type configuration with the proton of the exocyclic 9-amino group shifted on N(10). Because of a severe steric interaction between the nitro group in the 1-position and the chelate diamine chain in the 9-position, the acridine moiety is folded about the C(9)-N(10) vector with an average angle between outer rings of 12 degrees. Moreover, the acridine aromatic moiety and the platinum coordination planes are twisted, forming a dihedral angle of ca. 20 degrees. The steric repulsion between the nitro and the diamine groups appears to provide the driving force to metalation. The H(10) proton has a great tendency to be engaged in H-bonding as shown by X-ray and solution studies. The formation of a H-bond with a rather poor acceptor such as the chloride ion can cause a downfield shift of the H-resonance as large as 6 ppm.