Sequence specific suppression of androgen receptor-DNA binding in vivo by a Py-Im polyamide.

The crucial role of androgen receptor (AR) in prostate cancer development is well documented, and its inhibition is a mainstay of prostate cancer treatment. Here, we analyze the perturbations to the AR cistrome caused by a minor groove binding molecule that is designed to target a sequence found in a subset of androgen response elements (ARE). We find treatment with this pyrrole-imidazole (Py-Im) polyamide exhibits sequence selectivity in its repression of AR binding in vivo. Differentially changed loci are enriched for sequences resembling ARE half-sites that match the Py-Im polyamide binding preferences determined in vitro. Comparatively, permutations of the ARE half-site bearing single or double mismatches to the Py-Im polyamide binding sequence are not enriched. This study confirms that the in vivo perturbation pattern caused by a sequence specific polyamide correlates with its in vitro binding preference genome-wide in an unbiased manner.

Potent and Prolonged Innate Immune Activation by Enzyme-Responsive Imidazoquinoline TLR7/8 Agonist Prodrug Vesicles.

Synthetic immune-stimulatory drugs such as agonists of the Toll-like receptors (TLR) 7/8 are potent activators of antigen-presenting cells (APCs), however, they also induce severe side effects due to leakage from the site of injection into systemic circulation. Here, we report on the design and synthesis of an amphiphilic polymer-prodrug conjugate of an imidazoquinoline TLR7/8 agonist that in aqueous medium forms vesicular structures of 200 nm. The conjugate contains an endosomal enzyme-responsive linker enabling degradation of the vesicles and release of the TLR7/8 agonist in native form after endocytosis, which results in high in vitro TLR agonist activity. In a mouse model, locally administered vesicles provoke significantly more potent and long-lasting immune stimulation in terms of interferon expression at the injection site and in draining lymphoid tissue compared to a nonamphiphilic control and the native TLR agonist. Moreover, the vesicles induce robust activation of dendritic cells in the draining lymph node in vivo.

Oxiconazole nitrate solid lipid nanoparticles: formulation, in-vitro characterization and clinical assessment of an analogous loaded carbopol gel.

The aim of the present work was to develop a promising drug delivery system of oxiconazole nitrate-loaded solid lipid nanoparticles (SLNs) topical gel to enhance the drug effectiveness for the treatment of Tinea infection. SLNs were prepared by emulsification-solvent evaporation method. Particle size and entrapment efficiency of the prepared SLNs were investigated. An appropriate formulation was selected and examined for morphology and physicochemical characterization adopting Scanning electron microscope and Differential scanning colorimetry. In-vitro drug release was also investigated. The selected SLNs were loaded into 1% Carbopol 934 gel that was investigated for homogeneity, pH, grittiness, spreadability, viscosity and in vitro drug release. Clinical study for the developed gel system compared to the corresponding marketed product was conducted on 28 patients. The results revealed that the prepared oxiconazole nitrate SLNs had drug entrapment efficiency ranging from 41.34% to 75.07% and zeta potential lying between -13 and -50. Physicochemical characterization revealed a decrease in the drug crystallinity in the prepared SLNs. The gel formulation showed appropriate physical characteristics and sustained in-vitro drug release. Clinical study for the prepared oxiconazole nitrate SLNs gel showed significantly less side effects, better patient satisfaction and superior clinical improvement compared with the corresponding marketed product.

Sequence-Selective Minor Groove Recognition of a DNA Duplex Containing Synthetic Genetic Components.

The structural basis of minor groove recognition of a DNA duplex containing synthetic genetic information by hairpin pyrrole-imidazole polyamides is described. Hairpin polyamides induce a higher melting stabilization of a DNA duplex containing the unnatural P·Z base-pair when an imidazole unit is aligned with a P nucleotide. An NMR structural study showed that the incorporation of two isolated P·Z pairs enlarges the minor groove and slightly narrows the major groove at the site of this synthetic genetic information, relative to a DNA duplex consisting entirely of Watson-Crick base-pairs. Pyrrole-imidazole polyamides bind to a P·Z-containing DNA duplex to form a stable complex, effectively mimicking a G·C pair. A structural hallmark of minor groove recognition of a P·Z pair by a polyamide is the reduced level of allosteric distortion induced by binding of a polyamide to a DNA duplex. Understanding the molecular determinants that influence minor groove recognition of DNA containing synthetic genetic components provides the basis to further develop unnatural base-pairs for synthetic biology applications.

Superiority of DEAE-Dx-Stabilized Cationic Bile-Based Vesicles over Conventional Vesicles for Enhanced Hepatic Delivery of Daclatasvir.

The purpose of our study was to improve the delivery of a direct-acting antiviral drug, daclatasvir, to the site of action, liver tissues, using physically and biologically stable cationic bile-based vesicles. Accordingly, cationic bile-based vesicles were prepared as pro-bile-based vesicles and diethylaminoethyl dextran (DEAE-Dx)-stabilized bile-based vesicles to increase their stability without negatively affecting their hepatic affinity. The prepared bile-based vesicles were characterized for particle size, polydispersity index, ζ-potential, in vitro daclatasvir release, and ex vivo permeation using non-everted gut sac intestine. The in vivo biodistribution was experimented after oral administration utilizing the radiolabeling assay, where the liver showed the highest accumulation of the DEAE-Dx-stabilized bile-based vesicles after 4 h, reaching a value of 4.6% ID/g of the total oral administered dose of the labeled drug compared to drug solution, pro-bile-based vesicles, and cationic bile-based vesicles where the accumulation was 0.19, 1.3, and 0.31% ID/g, respectively. DEAE-Dx-stabilized bile-based vesicles increased the drug deposition into the liver about 42-fold compared to oral solution. The high physical stability and the high resistance to opsonization and clearance show that DEAE-Dx-stabilized bile-based vesicles could be efficiently applied for enhancing daclatasvir delivery to the liver after oral administration.

Orientation preferences of hairpin pyrrole-imidazole polyamides toward mCGG site.

Hairpin pyrrole-imidazole (Py-Im) polyamides are promising medium-sized molecules that bind sequence-specifically to the minor groove of B-form DNA. Here, we synthesized a series of hairpin Py-Im polyamides and explored their binding affinities and orientation preferences to methylated DNA with the mCGG target sequence. Thermal denaturation assays revealed that the five hairpin Py-Im polyamides, which were anticipated to recognize mCGG in a forward orientation, bind to nontarget DNA, GGmC, in a reverse orientation. Therefore, we designed five Py-Im polyamides that could recognize mCGG in a reverse orientation. We found that the two Py-Im polyamides containing Im/ß pairs preferentially bound to mCGG in a reverse orientation. The reverse binding Py-Im polyamide successfully inhibited TET1 binding on the methylated DNA. Taken together, this study illustrated the importance of designing reverse binding Py-Im polyamides for the target sequence, mCGG, which paved the way for Py-Im polyamides that can be used with otherwise difficult to access DNA with CG sequences.

RNA polymerase II senses obstruction in the DNA minor groove via a conserved sensor motif.

RNA polymerase II (pol II) encounters numerous barriers during transcription elongation, including DNA strand breaks, DNA lesions, and nucleosomes. Pyrrole-imidazole (Py-Im) polyamides bind to the minor groove of DNA with programmable sequence specificity and high affinity. Previous studies suggest that Py-Im polyamides can prevent transcription factor binding, as well as interfere with pol II transcription elongation. However, the mechanism of pol II inhibition by Py-Im polyamides is unclear. Here we investigate the mechanism of how these minor-groove binders affect pol II transcription elongation. In the presence of site-specifically bound Py-Im polyamides, we find that the pol II elongation complex becomes arrested immediately upstream of the targeted DNA sequence, and is not rescued by transcription factor IIS, which is in contrast to pol II blockage by a nucleosome barrier. Further analysis reveals that two conserved pol II residues in the Switch 1 region contribute to pol II stalling. Our study suggests this motif in pol II can sense the structural changes of the DNA minor groove and can be considered a "minor groove sensor." Prolonged interference of transcription elongation by sequence-specific minor groove binders may present opportunities to target transcription addiction for cancer therapy.

Hydrophobic structure of hairpin ten-ring pyrrole-imidazole polyamides enhances tumor tissue accumulation/retention in vivo.

To examine the hydrophobic structure of PI polyamides on tumor accumulation in vivo, PI polyamide-fluorescein conjugates 1-5 with the distinct number of N-methylimidazole (Im) units were synthesized. There existed an inverse relationship between the Im unit number of the compounds and their hydrophobicity. Compound 1 with one Im unit and 3 with three Im units accumulated and retained preferentially in tumor tissues compared to 5 with five Im units. These results suggest the importance of a PI polyamide's primary structure, which partly contributes to its hydrophobic property, on its accumulation and/or retention in tumor tissues in vivo.

Genome-Wide Assessment of the Binding Effects of Artificial Transcriptional Activators by High-Throughput Sequencing.

One of the major goals in DNA-based personalized medicine is the development of sequence-specific small molecules to target the genome. SAHA-PIPs belong to such class of small molecule. In the context of the complex eukaryotic genome, the differential biological effects of SAHA-PIPs are unclear. This question can be addressed by identifying the binding regions across the genome; however, it is a challenge to enrich small-molecule-bound DNA without chemical crosslinking. Here, we developed a method that employs high-throughput sequencing to map the binding area of small molecules throughout the chromatinized human genome. Analysis of the sequenced data confirmed the presence of specific binding sites for SAHA-PIPs from the enriched sequence reads. Mapping the binding sites and enriched regions on the human genome clarifies the reason for the distinct biological effects of SAHA-PIP. This approach will be useful for identifying the function of other small molecules on a large scale.

Structural features affecting the enzymatic digestibility of pine wood pretreated with ionic liquids.

Pretreating lignocellulosic biomass with certain ionic liquids results in structural and chemical changes that make the biomass more digestible by enzymes. In this study, pine wood was pretreated with 1-ethyl-3-methylimidazolium chloride/acetate ([C2 mim]Cl and [C2 mim][OAc]) at different temperatures to investigate the relative importance of substrate features, such as accessible surface area, cellulose crystallinity, and lignin content, on enzymatic digestibility. The ionic liquid pretreatments resulted in glucan conversions ranging from 23% to 84% on saccharification of the substrates, with [C2 mim][OAc] being more effective than [C2 mim]Cl. The pretreatments resulted in no delignification of the wood, some loss of cellulose crystallinity under certain conditions, and varying levels of increased surface area. Enzymatic digestibility closely correlated with accessible surface area and porosity measurements obtained using Simons' staining and thermoporosimetry techniques. Increased accessible surface area was identified as the principal structural feature responsible for the improved enzymatic digestibility.

Binding and biomimetic cleavage of the RNA poly(U) by synthetic polyimidazoles.

Four polyimidazoles were used in the binding and cleavage studies with poly(U). The two polydisperse polyvinylimidazoles were previously described by others, while the other two new polymers of polyethyleneimines were prepared by cationic polymerization of oxazolines. The latter had imidazole units attached to each nitrogen of the polymers. They were characterized by gel permeation chromatography and had very low polydispersities. When they were partially protonated they bound to the poly(U) and catalyzed its cleavage by a process analogous to that used by the enzyme ribonuclease A. The kinetics of the cleavage were followed by an assay we had previously described using phosphodiesterase I from Crotalus venom after the cleavage processes. Cleavage of poly(U) with Zn(2+) was also examined, with and without the polymers. A scheme is described in which these cleavages could be made sequence selective with various RNAs, particularly with important targets, such as viral RNAs.

Gene expression changes in a tumor xenograft by a pyrrole-imidazole polyamide.

Gene regulation by DNA binding small molecules could have important therapeutic applications. This study reports the investigation of a DNA-binding pyrrole-imidazole polyamide targeted to bind the DNA sequence 5'-WGGWWW-3' with reference to its potency in a subcutaneous xenograft tumor model. The molecule is capable of trafficking to the tumor site following subcutaneous injection and modulates transcription of select genes in vivo. An FITC-labeled analogue of this polyamide can be detected in tumor-derived cells by confocal microscopy. RNA deep sequencing (RNA-seq) of tumor tissue allowed the identification of further affected genes, a representative panel of which was interrogated by quantitative reverse transcription-PCR and correlated with cell culture expression levels.

Next-generation sequencing studies guide the design of pyrrole-imidazole polyamides with improved binding specificity by the addition of ß-alanine.

The identification of binding sites for small molecules in genomic DNA is important in various applications. Previously, we demonstrated rapid transcriptional activation by our small molecule SAHA-PIP. However, it was not clear whether the strong biological effects exerted by SAHA-PIP were attributable to its binding specificity. Here, we used high-throughput sequencing (Bind-n-seq) to determine the binding specificity of SAHA-PIPs. Sequence specificity bias was determined for SAHA-PIPs (3 and 4), and this showed enhanced 6 bp sequence-specific binding compared with hairpin PIPs (1 and 2). This finding allowed us to investigate the role of the ß-alanine that links SAHA to PIP, and led in turn to the design of ßß-PIPs (5 and 6), which showed enhanced binding specificity. Overall, we demonstrated the importance of ß-moieties for the binding specificity of PIPs and the use of cost-effective high-throughput screening of these small molecules for binding to the DNA minor groove.

Molecular parameters and transmembrane transport mechanism of imidazolium-functionalized binols.

We describe the molecular parameters governing the transmembrane activity of imidazolium-functionalized anion transporters and present a detailed mechanistic study. These ionophores adopt a mobile-carrier mechanism for short methyl and butyl chains, a combined mobile-carrier/transmembrane-pore mechanism for octyl and dodecyl chains, and form transmembrane aggregates for hexadecyl chains.

Charge engineering of cellulases improves ionic liquid tolerance and reduces lignin inhibition.

We report a novel approach to concurrently improve the tolerance to ionic liquids (ILs) as well as reduce lignin inhibition of Trichoderma reesei cellulase via engineering enzyme charge. Succinylation of the cellulase enzymes led to a nearly twofold enhancement in cellulose conversion in 15% (v/v) 1-butyl-3-methylimidazolium chloride ([BMIM][Cl]). The improvement in activity upon succinylation correlated with the apparent preferential exclusion of the [Cl] anion in fluorescence quenching assays. Additionally, modeling analysis of progress curves of Avicel hydrolysis in buffer indicated that succinylation had a negligible impact on the apparent KM of cellulase. As evidence of reducing lignin inhibition of T. reesei cellulase, succinylation resulted in a greater than twofold increase in Avicel conversion after 170 h in buffer with 1 wt% lignin. The impact of succinylation on lignin inhibition of cellulase further led to the reduction in apparent KM of the enzyme cocktail for Avicel by 2.7-fold. These results provide evidence that naturally evolved cellulases with highly negative surface charge densities may similarly repel lignin, resulting in improved cellulase activity. Ultimately, these results underscore the potential of rational charge engineering as a means of enhancing cellulase function and thus conversion of whole biomass in ILs.

Syntheses and structure-activity relationships for some triazolyl p38α MAPK inhibitors.

The design, synthesis and biological evaluation of novel triazolyl p38α MAPK inhibitors with improved water solubility for formulation in cationic liposomes (SAINT-O-Somes) targeted at diseased endothelial cells is described. Water-solubilizing groups were introduced via a 'click' reaction of functional azides with 2-alkynyl imidazoles and isosteric oxazoles to generate two small libraries of 1,4-disubstituted 1,2,3-triazolyl p38α MAPK inhibitors. Triazoles with low IC50 values and desired physicochemical properties were screened for in vitro downregulation of proinflammatory gene expression and were formulated in SAINT-O-Somes. Triazolyl p38α MAPK inhibitor 88 (IC50=0.096 µM) displayed the most promising in vitro activity.

A C-14 labeled Py-Im polyamide localizes to a subcutaneous prostate cancer tumor.

In an effort to quantitate Py-Im polyamide concentrations in vivo, we synthesized the C-14 radioactively labeled compounds 1-3, and investigated their tumor localization in a subcutaneous xenograft model of prostate cancer (LNCaP). Tumor concentrations were compared with representative host tissues, and exhibited a certain degree of preferential localization to the xenograft. Compound accumulation upon repeated administration was measured. Py-Im polyamide 1 was found to accumulate in LNCaP tumors at concentrations similar to the IC50 value for this compound in cell culture experiments.

Comparison of different ionic liquids pretreatment for corn stover enzymatic saccharification.

Recently, application of ionic liquids (ILs) has received much attention due to their special solvency properties as a promising method of pretreatment for lignocellulosic biomass. Easy recovery of ionic liquids, chemical stability, temperature stability, nonflammability, low vapor pressure, and wide liquidus range are among those unique properties. These solvents are also known as green solvents due to their low vapor pressure. The present study was set to compare the effect of five different ILs, namely, 1-ethyl-3-methylimidazolium acetate ([EMIM][Ac]), 1-butyl-3-methylimidazolium chloride ([BMIM][Cl]), 1-ethyl-3-methyl imidazolium diethyl phosphate ([EMIM][DEP]), 1-allyl-3-methylimidazolium chloride ([AMIM][Cl]), and 1-ethyl-3-methylimidazolium-hydrogen sulfate ([EMIM][HSO4]), on corn stover in a bioethanol production process. The performance of ILs was evaluated based on the change observed in chemical structure, crystallinity index, cellulose digestibility, and glucose release. Overall, [EMIM][Ac]-pretreated corn stover led to significantly higher saccharification, with cellulose digestibility reaching 69% after 72 hr, whereas digestibility of untreated barley straw was measured at only 21%.

Conformational modulation of DNA by polyamide binding: structural effects of f-Im-Py-Im based derivatives on 5'-ACGCGT-3'.

The DNA sequence 5'-ACGCGT-3' is in the core site of the Mlu 1 cell-cycle box, a transcriptional element in the promoter region of human Dbf4 gene that is highly correlated with a large number of aggressive solid cancers. The polyamide formamido-imidazole-pyrrole-imidazole-amine(+) (f-Im-Py-Im-Am(+) ) can target the minor groove of 5'-ACGCGT-3' as an antiparallel stacked dimer and has shown good activity in inhibiting transcription factor binding. Recently, f-Im-Py-Im-Am(+) derivatives that involve different orthogonally positioned substituents were synthesized to target the same binding site, and some of them have displayed improved binding and pharmacological properties. In this study, the gel electrophoresis-ligation ladders assay was used to evaluate the conformational effects of f-Im-Py-Im-Am(+) and derivatives on the target DNA, an essential factor for establishing the molecular basis of polyamide-DNA complexes and their transcription factor inhibition. The results show that the ACGCGT site in DNA has a relatively wide minor groove and a B-form like overall structure. After binding with f-Im-Py-Im-Am(+) derivatives, the DNA conformation is changed as indicated by the different mobilities in the gel. These conformational effects on DNA will at least help to point to the mechanism for the observed Mlu 1 inhibition activity of these polyamides. Therefore, modulating DNA transcription by locking the DNA shape or altering the minor groove geometry to affect the binding affinity of certain transcription factors is an attractive possible therapeutic mechanism for polyamides. Some of the substituents are charged with electrostatic interactions with DNA phosphate groups, and their charge effects on DNA gel mobility have been observed.

Pyrrole-imidazole polyamides distinguish between double-helical DNA and RNA.

Groove specificity: pyrrole-imidazole polyamides are well-known for their specific interactions with the minor groove of DNA. However, polyamides do not show similar binding to duplex RNA, and a structural rationale for the molecular-level discrimination of nucleic acid duplexes by minor-groove-binding ligands is presented.