Ca2+ Selective Host Rotaxane Is Highly Toxic Against Prostate Cancer Cells.

New therapies are needed to eradicate androgen resistant, prostate cancer. Prostate cancer usually metastasizes to bone where the concentration of calcium is high, making Ca2+ a promising toxin. Ionophores can deliver metal cations into cells, but are currently too toxic for human use. We synthesized a new rotaxane (CEHR2) that contains a benzyl 15-crown-5 ether as a blocking group to efficiently bind Ca2+. CEHR2 transfers Ca2+ from an aqueous solution into CHCl3 to greater extent than alkali metal cations and Mg2+. It also transfers Ca2+ to a greater extent than CEHR1, which is a rotaxane with an 18-crown-6 ether as a blocking group. CEHR2 was more toxic against the prostate cancer cell lines PC-3, 22Rv1, and C4-2 than CEHR1. This project demonstrates that crown ether rotaxanes can be designed to bind a targeted metal cation, and this selective cation association can result in enhanced toxicity.

A Versatile Axle for the Construction of Disassemblage Rotaxanes.

Rotaxanes are unique mechanical devices that hold great promise as sensors. We report on two new rotaxanes that contain an acid or base sensitive trigger and readily disassemble in a wide range of environments. Disassemblage was observed under TLC and ¹H-NMR analysis. The axle is highly charged, which enhances solubility in aqueous environments, and can be readily derivatized with sensor components. The trigger was swapped in a one-pot method, which is promising for the rapid production of a series of sensors.

Crown Ether Host-Rotaxanes as Cytotoxic Agents.

Highly toxic bacterial ionophores are commonly used in veterinary medicine, but their therapeutic index is too narrow for human usage. With the goal of developing ionophores with a broader therapeutic index, we constructed highly derivatized synthetic ionophores. The toxicities of crown ether host-rotaxanes (CEHR's) against the SKOV-3 cell line were measured. The effect of Mg2+ or Ca2+ on toxicity was explored because changes in the intracellular concentration of these cations can cause cell death through apoptosis. We found Boc-CEHR is highly toxic and Arg-CEHR is slightly less toxic with IC50 values of 0.5 µM and 6 µM, respectively, in standard growth medium. Increasing the concentration of Ca2+ resulted in greater toxicity of the CEHRs, whereas increasing the concentration of Mg2+ was less effective on reducing IC50. Cell death occurs mainly through apoptosis. Although preliminary, these results suggest that the CEHRs deliver Ca2+ and perhaps Mg2+ into cells inducing apoptosis.

Pt-rotaxanes as cytotoxic agents.

Cytotoxic agents that specifically target cancer cells are in high demand. Modifying drugs with targeting groups however, can produce deleterious effects on drug pharmokinetics. In this study, platinum (Pt) was linked with host-rotaxanes to discover the effect on the cytotoxicity of Pt when carried by a highly modified rotaxane as a ligand. One host-rotaxane (Pt-BocRot) contains the basic components of a rotaxane: wheel (with a Boc protecting group), axle, and blocking group. A second rotaxane (Pt-ArgRot) contains arginine moieties on its wheel instead to potentially improve association with the phosphate groups on cell membranes or DNA backbone. The cytotoxicities of the rotaxanes and various model compounds were determined using ovarian cancer SKOV-3 cell line, which is resistant to cisplatin. We found Pt-ArgRot was slightly more cytotoxic than Pt-BocRot. Both were clearly more cytotoxic than rotaxanes without Pt and the model compounds. As importantly, they killed cells through an apoptotic mechanism. These results suggest that targeting agents for a particular cell type can be incorporated with Pt-complexes using the rotaxane architecture to improve drug specificity.

Synthesis and investigation of host-[2]rotaxanes that bind metal cations.

Materials that bind metal cations are highly sought after for new devices. In this report, we show that rotaxanes can transfer metal cations with picrate, perchlorate, or chloride counterions from an aqueous solution into chloroform. The rotaxanes contain a dibenzyl-24-crown-8 ether as the wheel with either a benzyl-18-crown-6 ether (CEBG-R1-3) or a 3,5-dimethylbenzyl moiety (ArBG-R) as one blocking group. Alkali and alkaline picrate salts were efficiently extracted from an aqueous solution, presented in the millimolar range, into chloroform. Large association constants were derived for the complexes in chloroform, especially for the divalent cation Mg(2+). Switching the counterion to chloride greatly diminished the amount of salt extracted. To explore the transfer mechanism of the rotaxanes, a comparison was made in the amount of NaClO(4), KClO(4), NaCl, and KCl extracted by CEBG-R1, ArBG-R, benzyl-18-crown-6 ether (B18C6), and two model compounds, which were used to represent the crown-ether blocking group and the axle of a rotaxane. Two-dimensional NMR analysis was performed on the rotaxane-cation complexes in CDCl(3). We found that the host rotaxanes transfer the perchlorate salts poorly when compared to B18C6, but they transfer chloride salts from 1 M salt solutions, whereas B18C6 does not. The transfer of chloride salts appears to rely on an allosteric type relationship between the binding of the chloride ion and metal cation to a rotaxane. Accordingly, when chloride binds to the dialkylammonium ion of the axle, the wheel moves along the axle and forms a binding site for a metal cation. In this report we demonstrate that host rotaxanes can bind metal cations, change their geometries upon cation and anion association, and operate through allosteric mechanisms, making them promising candidates for molecular devices.

Host-rotaxanes with oligomeric axles are intracellular transport agents.

Polymeric macromolecules are promising drug delivery devices with endocytotic properties that need to be resolved. Host-rotaxanes (HRs) also deliver materials into cells but require improved in vivo targeting capacity. Combining the targeting properties of nanoparticles with the transport function of HRs may improve drug efficacy. Our prototype HR (HR 1) has a short axle and is an efficient transporter. Here, we have constructed HRs that contain an oligo(ethylene glycol) (HR 2) or an oligoalkyl (HR 3) axle with the future goal of combining them with nanoparticles. HR 2 more efficiently delivers Fl-peptides into ovarian cancer cells than HR 3 and, in most cases, than HR 1. HR 2 appears to possess the appropriate balance between water solubility and lipophilicity to be an efficient transporter along with a suitable structure for incorporation into a larger nanoparticle.

Host-rotaxanes model proteins that promote ligand association through a favorable change in configurational entropy.

Proteins can reduce the entropic penalty for ligand association through a favorable change in configurational entropy. To investigate this process, the Delta G(o), Delta H(o), and DeltaS(o) of complexes formed between host-rotaxanes and guests were determined and compared to discover the relationship between rotaxane-structure and the energies involved in guest-association in water and DMSO. Fluorescence quenching assays provided the association constants. Van't Hoff analysis of variable temperature assays gave the enthalpies of binding. The driving force for the association of a guest and a host-rotaxane can switch from being enthalpically to entropically driven with a change in the solvent or guest. This study shows that a dramatic increase in the entropy of binding can be obtained through the addition of a rotaxane-wheel to a synthetic host. An increased motion of the wheel appears to be the source of the positive binding entropy, which would be an example of favorable configurational entropy promoting complex formation.

A host-rotaxane derivatized with carboxylic acids efficiently delivers a highly cationic fluoresceinated peptide.

A cleft-[2]rotaxane (CR2+2-) was derivatized with carboxylic acids to enhance the intracellular delivery of a highly cationic or anionic pentapeptide. CR2+2- delivers the fluorescein (Fl) tagged peptide Fl-KKALR to a greater amount than Fl-QEAVD, and at a higher concentration, a greater amount than Fl-AVWAL. The level of delivery is largely temperature and ATP independent, suggesting that the Fl-peptide.CR2+2- complexes pass through the cellular membrane without requiring active cell-mediated processes. This study shows that selective delivery of peptides is possible by using a suitably derivatized host-rotaxane as the transporter.

Determining the binding and intracellular transporting abilities of a host-[3]rotaxane.

The cellular permeability of compounds can be enhanced in the presence of a host-[2]rotaxane (HR). The effective concentration of an HR is limited by the stoichiometry of the complex formation of the HR and the delivered compound. We speculate that a complex forms between the HR and a guest during membrane passage. To further explore the relationship between guest binding and guest delivery and to obtain more efficient delivery devices, we present, in this report, the first example of a cyclophane-[3]rotaxane (Cy3R), which has two wheels and a cyclophane as a blocking group. The properties of Cy3R were compared to a new cyclophane-[2]rotaxane (Cy2R) that has the same cyclophane pocket as Cy3R but only a single wheel. The second wheel of Cy3R can form additional noncovalent bonds, e.g., salt bridges, cation-pi interactions or aromatic-aromatic interactions, with appropriately functionalized guests. We show by flow cytometric analysis that Cy3R transfers Fl-AVWAL (76%) and to a lesser degree Fl-QEAVD (26%) into live cells. The level of Fl-peptide within a cell is concentration dependent and largely temperature and ATP independent, suggesting that a Cy3R.Fl-peptide complex passes through the cellular membrane without requiring active cell-mediated processes. Cy2R, on the other hand, forms weaker complexes and requires a higher concentration to transfer materials into cells. These results demonstrate that the addition of a second wheel on a rotaxane can improve guest binding in various solvents and hence delivery through cellular membranes.

Investigation of the intracellular delivery of fluoresceinated peptides by a host-[2]rotaxane.

The development of methods to transport peptides into cells via a passive mechanism would greatly aid in the development of therapeutic agents. We recently demonstrated that an impermeable fluoresceinated pentapeptide enters the cytoplasm and nucleus of COS 7 cells in the presence of a host-[2]rotaxane by a mechanism that does not depend on an active cell-mediated process. In this report, we further investigate the ability of the host-[2]rotaxane to deliver peptides possessing a wide range of polarities (negatively charged, positively charged, polar, and apolar side chains) into live cells. Only in the presence of the host-[2]rotaxane were the Fl-peptides taken up by COS 7 and ES2 cells. Flow cytometry experiments demonstrated that the level of delivery is largely temperature and adenosine 5'-triphosphate (ATP) independent, and the membranes remain intact. Although the level of transport does depend upon the nature of the side chains, it does not correlate with calculated LogD values, indicating that an additional interaction with the host-[2]rotaxane is modifying the permeability properties of the peptide. The amount of Fl-peptides transported from an aqueous phase into a chloroform phase in the presence of the host-[2]rotaxane correlates with the intensity of cellular fluorescence. Extraction and U-tube studies show that the Fl-peptide can be released from its complex with the host-[2]rotaxane into an aqueous phase, and the host-[2]rotaxane can transport a greater than a stoichiometric amount of an Fl-peptide through a CHCl3 layer. These studies demonstrate the utility of the host-[2]rotaxane in delivering peptides of all polarities across a cell membrane.

Determining the intracellular transport mechanism of a cleft-[2]rotaxane.

Rotaxanes are a class of interlocked compounds that have been extensively investigated for their potential utility as switches or sensors. We recently demonstrated that rotaxanes have further application as agents that transport material into cells. This novel finding prompted our investigation into the mechanism by which rotaxanes are involved in transmembrane transport. Two-dimensional NMR analysis showed that a cleft-containing rotaxane exists in two dominant conformations ("closed" and "open"). To determine the importance of conformational flexibility on the ability of the rotaxanes to bind guests and transport material into cells, the rotaxane was chemically modified to lock it in the closed conformation. Charged guests interact less favorably with the locked rotaxane, as compared to the unmodified rotaxane, both in an aqueous solution and in DMSO. In a chloroform solution, both rotaxanes bind the guests with similar affinities. The locked rotaxane exhibited a reduced capacity to transport a fluoresceinated peptide into cells, whereas the unmodified rotaxane efficiently delivers the peptide. Flow cytometry experiments demonstrated that a high percentage of the cells contained the delivered peptide (89-98%), the level of delivery is concentration dependent, and the rotaxanes and peptide have low toxicity. Cellular uptake of the peptide was largely temperature and ATP independent, suggesting that the rotaxane-peptide complex passes through the cellular membrane without requiring active cell-mediated processes. The results show that the sliding motion of the wheel is necessary for the delivery of materials into cells and can enhance the association of guests. These studies demonstrate the potential for rotaxanes as a new class of mechanical devices that deliver a variety of therapeutic agents into targeted cell populations.

Creation and investigation of protein-core mimetics with parallel and antiparallel aligned amino acids.

Mimetic protein cores were created that align a set of l-Phe, d-Phe, or l-Leu residues in a parallel or an antiparallel arrangement in chloroform. Not all cores show a single conformation at room temperature. Stable structures require a synergistic relationship between the H-bonding groups and the residues within the core. The spatial arrangement of the side chains dictates whether a zippered or a crossed pattern of H-bonds is observed for these cores. Variable-temperature (1)H NMR experiments were used to determine the strengths of the H-bonds. The existence of H-bonds was verified through FTIR spectroscopic analysis. Large temperature coefficients exist for some protons of aromatic rings that are held in a T-shaped arrangement. A comparison of these temperature coefficients shows that a more stable core is obtained by combining benzenoid and nitrobenzenoid rings as compared to benzenoid rings. Structures were determined using a combination of 2D NMR analysis and molecular modeling.

Host-[2]rotaxanes as cellular transport agents.

Host-[2]rotaxanes, containing a diarginine-derivatized dibenzo-24-crown-8 (DB24C8) ether as the ring and a cyclophane pocket or an aromatic cleft as one blocking group, are cell transport agents. These hosts strongly associate with a variety of amino acids, dipeptides, and fluorophores in water (1 mM phosphate buffer, pH 7.0), DMSO, and a 75/25 (v/v) buffer to DMSO solution. All peptidic guests in all solvent systems have association constants (K(A)'s) in the range of 1 x 10(4) to 5 x 10(4) M(-)(1), whereas the K(A) range for the fluorophores is 1 x 10(4) to 9 x 10(5) M(-)(1). Association constants for the cyclophane itself, cyclophane 3, are smaller. These values are in the 1 x 10(3) to 5 x 10(3) M(-)(1) range, which shows that the rotaxane architecture is advantageous for guest binding. Cyclophane-[2]rotaxane 1 efficiently transports fluorescein and a fluorescein-protein kinase C (PKC) inhibitor into eukaryotic COS-7 cells, including the nucleus. Interestingly, cleft-[2]rotaxane 2 does not transport fluorescein as efficiently, even though the results from the fluorescence assays show that both [2]rotaxanes bind fluorescein with the same ability.

Synthesis and evaluation of peptidomimetics that bind DNA.

A peptidomimetic template, consisting of a hydrophobic scaffold, a dansyl fluorophore, and an Arg-His recognition strand, was tested as a simple mimic of zinc finger 2 of the Zif268 protein. Association constants (K(A)'s) were on the order of 10(5) M(-1) for complexes formed between the mimetic and duplexes d(CGGGAATTCCCG)(2) and d(AAAAAAAAATTTTTTTTT)(2). Modest selectivity was observed for the GC-rich DNA in a 0.5M NaCl/buffer (0.1M phosphate, pH 7.0) solution. Differences in K(A)'s along with observed CD profiles suggest that the mimetic associated with the duplexes using different binding modes. The DNA duplexes had weaker interactions with the free Arg-His recognition strand, the dansyl functional group, and a scaffold that contained only glycines as the recognition strand. The scaffold most likely provides for greater van der Waal's interactions, a larger hydrophobic effect upon association, and reduces the freedom of motion of the side chains. This last effect was confirmed by molecular mechanics calculations and by the fact that the mimetic suffered a smaller loss of entropic energy upon association than the free recognition strand. These studies show that the synthetic scaffold is a promising platform in which peptides can be attached to increase their affinity and possibly selectivity for DNA targets.

Structure-function relationship of amino acid-[2]rotaxanes.

Synthetic methodology was developed to construct amino acid-[2]rotaxanes that have phenylalanine and 3,5-di-tert-butylbenzene as blocking groups and dibenzo-24-crown-8, derivatized with either N-acetylargininyl or a carboxylic group, as the ring. A relative measure of the intramolecular interaction energies between the functional groups in DMSO/water mixtures is obtained by comparing their pK(a) values. Rotaxane structures were investigated through 2D NMR analysis and molecular dynamics simulations. Association constants for complexes of amino acids and rotaxanes in various protonation states were determined in a variety of solvent systems by (1)H NMR analysis. The unique intracomponent interactions that exist in the rotaxanes and their ability to act as artificial receptors are discussed.

Host-[2]rotaxane: advantage of converging functional groups for guest recognition.

A host-[2]rotaxane was constructed by converting a diaminophenylcalix[4]arene into a [2]rotaxane using the DCC-rotaxane method (Zehnder, D.; Smithrud, D. B. Org. Lett. 2001, 16, 2485-2486). N-Ac-Arg groups were attached to the dibenzo-24-crown-8 ring of the rotaxane to provide a convergent functional group. To demonstrate the advantage provided by the rotaxane architecture for recognition of guests that contain a variety of functional groups, association constants (K(A)) for N-Ac-Trp, indole, N-Ac-Gly, fluorescein, 1-(dimethylamino)-5-naphthalenesulfonate, and pyrene bound to the [2]rotaxane were determined by performing (1)H NMR and fluorescence spectroscopic experiments. The host-[2]rotaxane had the highest affinity for fluorescein with a K(A) = 4.6 x 10(6) M(-)(1) in a 98/2 buffer (1 mM phosphate, pH 7)/DMSO solution. A comparison of K(A) values demonstrates that both the aromatic pocket and ring of the host-[2]rotaxane contribute binding free energy for complexation. Association constants were also derived for the same guests bound to the diaminophenylcalix[4]arene and to a diphenylcalix[4]arene that contained arginine residues displayed in a nonconvergent fashion. The host-[2]rotaxane provides higher affinity and specificity for most guests than the host with divergent N-Ac-Arg groups of the one that only has an aromatic pocket. For example, the K(A) for the complex of the host-[2]rotaxane and fluorescein in the DMSO/water mixture is more than 2 orders of magnitude greater than association constants derived for the other hosts.

Investigation of synthetic hosts that model cation-pi sites found at protein binding domains.

Small cyclophanes containing aromatic groups and dialkyl ammonium ions were created as model systems of the cation-pi complexes found at some protein binding domains. The hosts had different shapes in order to investigate the effect the arrangement of ammonium ions to aromatic surfaces has on their reactivity. pK(a) values of the hosts were substantially different in DMSO or (95/5) DMSO/D(2)O solutions, which showed that the ions existed in different environments of the hosts. Electrostatic charges, as determined by density functional calculations, revealed that the magnitude of a cationic charge depends on its position relative to an aromatic ring. Association constants of the hosts bound to the sodium salt of N-acetyl phenylalanine in d(6)-DMSO and in (95/5) d(6)-DMSO/D(2)O solutions were inversely proportional to the magnitude of the hosts' acidity constants. These results suggest that the magnitude of the positive charge for cationic groups of cation-pi complexes is reduced by being associated with electron-rich faces of aromatic rings. The aromatic rings, however, lessen the desolvation penalty that must be overcome for ligand binding, giving an overall more favorable association.

Carboxylates stacked over aromatic rings promote salt bridge formation in water.

Several salt bridges observed in protein X-ray crystallographic structures showed a consistent pattern of a carboxylate, situated near the face of an aromatic ring, forming a bond to an arginine residue of a ligand. To determine the driving force for these complexes, (1)H NMR or potentiometric binding titrations were performed on solutions containing N-acetyl arginine methyl ester, N-acetyl lysine methyl ester, guanidinium chloride, or KCl and one member of a series of diacidic templates, which had aromatic or aliphatic groups placed below their carboxylates. Only templates having an aromatic ring were able to form a salt bridge in water. Although most of the obvious interactions, such as ionic and cation-pi, and ion desolvation are important factors, association of an amino acid in water required the presence of the entire amino acid. This result suggests that the interaction between the aliphatic portion of an amino acid and an aromatic ring of a template is an important component of complexation. Aromatic templates also transported N-acetyl arginine methyl ester from water to 1-octanol. The results of the transport studies are discussed in terms of potential intermediate states that could lower some of the activation barriers of protein folding.