Modulating the Cellular Uptake of Fluorescently Tagged Substrates of Prostate-Specific Antigen before and after Enzymatic Activation.

A series of peptides based on the prostate-specific antigen (PSA)-specific sequence histidine-serine-serine-lysine-leucine-glutamine were functionalized with an anthraquinone fluorophore at the C-terminal residue side chain using the copper(I)-catalyzed azide-alkyne cycloaddition reaction. The effect of incorporating a negatively charged N-terminal tetra-glutamic acid group into the substrate and the effect of masking the negatively charged C-terminal carboxylic acid functionality of the substrate were investigated using confocal fluorescence microscopy in two cell lines, DLD-1 and LnCaP. The addition of a tetra-glutamic acid group to the N-terminus of the intact sequence was shown to reduce cellular uptake of the intact substrate prior to activation by PSA. In contrast, masking the C-terminal carboxylic acid group of the substrate as a methyl ester was shown to improve cellular uptake of the peptide fragment after activation by PSA. The synthesized C-terminal methyl ester substrates with the anthraquinone attached to the side chain were confirmed to be cleaved by PSA in LC-MS analysis, and the cytotoxicity of the substrates was shown to increase in the presence of PSA, consistent with cleavage and uptake of the C-terminal fragment. The results indicate that C- and N-terminal functionalization of peptide substrates targeting PSA can be used to modulate the cellular uptake of peptides before and after enzymatic activation, which may thus be an important consideration in the design of tumor-activated prodrugs.

Targeted Inhibition of Snail Activity in Breast Cancer Cells by Using a Co(III) -Ebox Conjugate.

The transition from a non-invasive to an invasive phenotype is an essential step in tumor metastasis. The Snail family of transcription factors (TFs) is known to play a significant role in this transition. These TFs are zinc fingers that bind to the CAGGTG Ebox consensus sequence. Co(III) -Ebox is a cobalt(III) complex attached to an Ebox oligonucleotide that confers specificity towards Snail TFs. Co(III) -Ebox has been shown to inhibit Snail-mediated embryonic neural crest development in Xenopus laevis, but its efficacy in inhibiting Snail-induced cancer cell invasiveness has not been explored. Here, we describe the efficacy of Co(III) -Ebox in inhibiting the invasive aspects of heregulin-ß1(HRG)-treated breast cancer cells. Co(III) -Ebox was found to inhibit the capacity of Snail to repress target genes after HRG induction. Snail inhibition by Co(III) -Ebox reduced the invasive propensity of cells in 2D and 3D, thereby demonstrating promise in inhibiting metastasis.

Cobalt derivatives as promising therapeutic agents.

Inorganic complexes are versatile platforms for the development of potent and selective pharmaceutical agents. Cobalt possesses a diverse array of properties that can be manipulated to yield promising drug candidates. Investigations into the mechanism of cobalt therapeutic agents can provide valuable insight into the physicochemical properties that can be harnessed for drug development. This review presents examples of bioactive cobalt complexes with special attention to their mechanisms of action. Specifically, cobalt complexes that elicit biological effects through protein inhibition, modification of drug activity, and bioreductive activation are discussed. Insights gained from these examples reveal features of cobalt that can be rationally tuned to produce therapeutics with high specificity and improved efficacy for the biomolecule or pathway of interest.

Dual targeting of hypoxic and acidic tumor environments with a cobalt(III) chaperone complex.

The rational design of prodrugs for selective accumulation and activation in tumor microenvironments is one of the most promising strategies for minimizing the toxicity of anticancer drugs. Manipulation of the charge of the prodrug represents a potential mechanism to selectively deliver the prodrug to the acidic tumor microenvironment. Here we present delivery of a fluorescent coumarin using a cobalt(III) chaperone to target hypoxic regions, and charged ligands for pH selectivity. Protonation or deprotonation of the complexes over a physiologically relevant pH range resulted in pH dependent accumulation of the fluorophore in colon cancer cells. Furthermore, in a spheroid solid tumor model, the anionic complexes exhibited preferential release of the fluorophore in the acidic/hypoxic region. By fine-tuning the physicochemical properties of the cobalt-chaperone moiety, we have demonstrated selective drug release in the acidic and hypoxic tumor microenvironment.

Effects of enzymatic activation on the distribution of fluorescently tagged MMP-2 cleavable peptides in cancer cells and spheroids.

A peptide tagged at the N-terminus with FITC, at the C-terminus with coumarin-343, and incorporating a sequence selectively cleaved by the matrix metalloproteinase, MMP-2, was synthesized to investigate the effect of peptide cleavage on both cellular accumulation and distribution in cancer cell spheroids. The peptide was shown by HPLC and mass spectroscopy to be cleaved in the presence of MMP-2 at the expected site. The cellular and spheroid distribution of each of the fragments was monitored using confocal fluorescence microscopy. The intact peptide had minimal accumulation in 2D-cultured DLD-1 cells that do not express MMP-2 in these conditions. Following addition of serum containing MMP-2 to the cell media, the cleaved C-terminal fragment was seen to enter the cells, while the N-terminal fragment remained extracellular, evidently blocked by the presence of the FITC group. 3D culture of DLD-1 cells as spheroids resulted in measurable MMP-2 activity. Different distribution patterns of the two fluorophores were seen in spheroids treated with the intact peptide, consistent with cleavage occurring. Different rates of accumulation of each of the fragments were observed within the spheroid over time, which is attributed to the extent of accumulation and sequestration of the fragments by cells residing in the periphery of the spheroids. The outcomes suggest that tumor-associated enzymes have the potential to modify the distribution of peptides and peptide fragments in solid tumors by modifying the cellular uptake of those peptides.

Iron(III) complexes of fluorescent hydroxamate ligands: preparation, properties, and cellular processing.

Iron(III) complexes containing hydroxamic acid fluorophores were investigated as models of hypoxia selective prodrugs in vitro. Two complexes were synthesised, [Fe(c343haH)(3)] and [Fe(salen)(c343haH)]. The fluorescence of the hydroxamate coumarin fluorophore was almost completely quenched on coordination to the iron(III) centre in [Fe(c343haH)(3)]. However, quenching was minimal for [Fe(c343haH)(salen)] in aqueous media and we propose that the fluorescence results from structural rearrangements that occur because of the inherent strain in the iron-salen structure. Fluorescence was also measured in the presence of the cellular reductants ascorbic acid and cysteine. Fluorescence intensity increased over time, with the most rapid return of fluorescence occurring over a two hr period. The rapid fluorescence return indicates that the complexes undergo ligand release, either via reduction followed by aquation, or via direct ligand exchange with the reductants. Electrochemical studies demonstrated that both complexes have very negative reduction potentials. Furthermore, [Fe(c343haH)(salen)] was shown to exhibit quasi-reversibility of reduction. The distribution of the free hydroxamate ligand and the complexes were monitored in A2780 cells. The free ligand displayed non-specific distribution, which differed from the nucleolar distribution of [Fe(c343haH)(3)] and the lysosomal accumulation of [Fe(c343haH)(salen)] over time. Thus the results of the present study show that iron(III) complexes present a viable model for monitoring hydroxamate fluorophore displacement in vitro to determine the fate of prodrugs.

Accumulation of an anthraquinone and its platinum complexes in cancer cell spheroids: the effect of charge on drug distribution in solid tumour models.

The penetration of anthraquinones and their platinum complexes into cancer cell spheroids reveals that they model well the distribution of such compounds in solid tumours and that the proportion of the compound that accumulates deep in the spheroid is inversely related to the rate of cellular uptake which is affected by the charge of the compound.

Cellular uptake and distribution of cobalt complexes of fluorescent ligands.

The development of complexes that allow the monitoring of the release and distribution of fluorescent models of anticancer drugs initially bound to cobalt(III) moieties is reported. Strong quenching of fluorescence upon ligation to cobalt(III) was observed for both the carboxylate- and the hydroximate-bound fluorophores as was the partial return of fluorescence following addition of ascorbate and cysteine. The extent of the increase in the fluorescence intensity observed following addition of these potential reductants is indicative of the fluorophore being displaced from the complex by the action of ascorbate or cysteine, by ligand exchange. The cellular distribution of the fluorescence revealed that coordination to cobalt can dramatically alter the subcellular distribution of a bound fluorophore. This work shows that fluorescence can be an effective means of monitoring these agents in cells, and of determining their sites of activation. The results also reveal that the cytotoxicity of such agents correlates with their uptake and distribution patterns and that these are influenced by the types of ligands attached to the complex.

Bioreductive activation and drug chaperoning in cobalt pharmaceuticals.

The potential for cobalt(III) complexes in medicine, as chaperones of bioactive ligands, and to target tumours through bioreductive activation, has been examined over the past 20 years. Despite this, chemical properties such as reduction potential and carrier ligands required for optimal tumour targeting and drug delivery have not been optimised. Here we review the chemistry of cobalt(III) drug design, and recent developments in the understanding of the cellular fate of these drugs.

Studies of a cobalt(III) complex of the MMP inhibitor marimastat: a potential hypoxia-activated prodrug.

We report a potential means of selectively delivering matrix metalloproteinase (MMP) inhibitors to target tumour sites by use of a bioreductively activated Co(III) carrier system. The carrier, comprising a Co(III) complex of the tripodal ligand tris(methylpyridyl)amine (tpa), was investigated with the antimetastatic MMP inhibitor marimastat (mmstH(2)). The X-ray crystal structure of [Co(mmst)(tpa)]ClO(4) x 4H(2)O was determined and two-dimensional NMR revealed the existence of two isomeric forms of the complex in solution. Electrochemical analysis showed that the reduction potential of the complex is suitable for it to be bioreductively activated at hypoxic tumour sites. In vitro assays confirmed the stability of the prodrug in solution prior to reduction and revealed very low cytotoxicity against A2780 cells. In vivo testing in mice showed a higher level of tumour-growth inhibition by the complex than by free marimastat. Both free marimastat and and its Co(III) complex increased metastasis in the model used, with the complex significantly more active.