SNP Discrimination by Tolane-Modified Peptide Nucleic Acids: Application for the Detection of Drug Resistance in Pathogens.

During the treatment of viral or bacterial infections, it is important to evaluate any resistance to the therapeutic agents used. An amino acid substitution arising from a single base mutation in a particular gene often causes drug resistance in pathogens. Therefore, molecular tools that discriminate a single base mismatch in the target sequence are required for achieving therapeutic success. Here, we synthesized peptide nucleic acids (PNAs) derivatized with tolane via an amide linkage at the N-terminus and succeeded in improving the sequence specificity, even with a mismatched base pair located near the terminal region of the duplex. We assessed the sequence specificities of the tolane-PNAs for single-strand DNA and RNA by UV-melting temperature analysis, thermodynamic analysis, an in silico conformational search, and a gel mobility shift assay. As a result, all of the PNA-tolane derivatives stabilized duplex formation to the matched target sequence without inducing mismatch target binding. Among the different PNA-tolane derivatives, PNA that was modified with a naphthyl-type tolane could efficiently discriminate a mismatched base pair and be utilized for the detection of resistance to neuraminidase inhibitors of the influenza A/H1N1 virus. Therefore, our molecular tool can be used to discriminate single nucleotide polymorphisms that are related to drug resistance in pathogens.

Evaluation of Meniscal Regeneration in a Mini Pig Model Treated With a Novel Polyglycolic Acid Meniscal Scaffold.

BACKGROUND: Meniscal injury is a severe impediment to movement and results in accelerated deterioration of the knee joint. PURPOSE: To evaluate the effect of a novel meniscal scaffold prepared from polyglycolic acid coated with polylactic acid/caprolactone on the treatment of meniscal injury in a mini pig model. STUDY DESIGN: Controlled laboratory study. METHODS: The model was established with a 10-mm resection at the anterior medial meniscus on both knee joints. A scaffold was implanted in the right knee joint. The meniscal scaffold was inserted and sutured next to the native meniscus. The histological analysis was performed to determine meniscal regeneration with safranin O staining, cell proliferation with PCNA, inflammation with TNF, and collagen structure and production with picrosirius red and immunofluorescence. Cartilage degeneration was evaluated with Safranin O. Meniscal regeneration and joint fluid were evaluated with magnetic resonance imaging. RESULTS: Although compressive stress and elastic modulus were significantly lower in the scaffold than in the native porcine menisci, ultimate tensile stress was similar. Implanted scaffolds were covered with tissue beginning at 4 weeks, with increased migration of proliferating cells to the implant area at 4 and 8 weeks. Scaffolds were absorbed with freshly produced collagen at 24 weeks. Cartilage degeneration was significantly lower in the meniscus-implanted group than in the meniscectomy group. Magnetic resonance imaging results did not show severe accumulation of joint fluids, suggesting negligible inflammation. Density of the implanted menisci was comparable with that of the native menisci. CONCLUSION: Meniscal scaffold prepared from polyglycolic acid has therapeutic potential for meniscal regeneration. CLINICAL RELEVANCE: This meniscal scaffold can improve biological knee reconstruction and prevent the increase of total knee arthroplasty.

Synthesis of neuraminidase-resistant sialoside-modified three-way junction DNA and its binding ability to various influenza viruses.

Natural sialic acid-modified compounds are capable of targeting influenza virus hemagglutinin (HA). However, these compounds have limited inhibitory effect because natural O-glycoside bond in these compounds are prone to be cleaved by neuraminidase (NA) on the surface of viruses. In this study, we synthesized NA-resistant sialoside that included unnatural S-glycoside bonds and modified this sialoside on a three-way junction (3WJ) DNA to display complementary distribution to its binding sites on a HA trimer. This S-glycoside-containing sialoside-modified 3WJ DNA showed certain NA resistance and maintained high binding affinity. Importantly, our observations showed that substituting natural O-glycoside with unnatural S-glycoside did not affect the binding affinity of the sialoside-modified 3WJ DNA for viruses. Thus, this study is an important step forward in the development of NA-resistant sialoside derivatives for more effective detection and inhibition of infection by a broad spectrum of viruses.

Binding inhibition of various influenza viruses by sialyllactose-modified trimer DNAs.

Sialyllactose (SL)-modified trimer DNAs with a similar SL presentation as their binding sites on influenza virus hemagglutinin (HA) trimer were designed and synthesized. These trimer DNAs showed high affinity for various influenza viruses, including A/Puerto Rico/08/34 (H1N1), A/Beijing/262/95 (H1N1), A/Yokohama/77/2008 (H1N1), and A/Panama/2007/99 (H3N2). Thus, presentation of SL residues on three vertexes of the scaffold as well as sialic acid binding sites on the HA trimer regardless of a tri-branched or triangular scaffold are important for high affinity for influenza viruses. These compounds have the potential for use in detection and as inhibitors of a broad spectrum of influenza viruses.

Antiviral Mechanism of Action of Epigallocatechin-3-O-gallate and Its Fatty Acid Esters.

Epigallocatechin-3-O-gallate (EGCG) is the major catechin component of green tea (Cameria sinensis), and is known to possess antiviral activities against a wide range of DNA viruses and RNA viruses. However, few studies have examined chemical modifications of EGCG in terms of enhanced antiviral efficacy. This paper discusses which steps of virus infection EGCG interferes with, citing previous reports. EGCG appears most likely to inhibits the early stage of infections, such as attachment, entry, and membrane fusion, by interfering with viral membrane proteins. According to the relationships between structure and antiviral activity of catechin derivatives, the 3-galloyl and 5'-OH group of catechin derivatives appear critical to antiviral activities. Enhancing the binding affinity of EGCG to virus particles would thus be important to increase virucidal activity. We propose a newly developed EGCG-fatty acid derivative in which the fatty acid on the phenolic hydroxyl group would be expected to increase viral and cellular membrane permeability. EGCG-fatty acid monoesters showed improved antiviral activities against different types of viruses, probably due to their increased affinity for virus and cellular membranes. Our study promotes the application of EGCG-fatty acid derivatives for the prevention and treatment of viral infections.

Sialyllactose-Modified Three-Way Junction DNA as Binding Inhibitor of Influenza Virus Hemagglutinin.

Sialic acid present on the cell surface is recognized by hemagglutinin (HA) on the influenza virus in the first step of infection. Therefore, a compound that can efficiently interfere with the interaction between sialic acid and HA might inhibit infection and allow detection of the influenza virus. We focused on the spatial arrangement of sialic acid binding sites on HA and developed 2,3-sialyllactose (2,3-SL)-modified three-way junction (3WJ) DNA molecules with a topology similar to that of sialic acid binding sites. 3WJ DNA with three 2,3-SL residues on each DNA strand showed (8.0 × 104)-fold higher binding affinity for influenza virus A/Puerto Rico/08/34 (H1N1) compared to the 2,3-SL. This result indicated that the glycocluster effect due to clustering on one DNA arm and optimal spatial arrangement of the 3WJ DNA improved the weak interactions between a sialic acid and its binding site on HA. This 3WJ DNA compound has possible application as an inhibitor of influenza infection and for virus sensing.

Dual-effect liposomes with increased antitumor effects against 67-kDa laminin receptor-overexpressing tumor cells.

This study sought to evaluate the antitumor effects of and elucidate the mechanisms underlying (-)-epigallocatechin-3-O-gallate (EGCG) and polyethyleneglycol (PEG)-modified liposomes. EGCG functions as a target ligand of the 67-kDa laminin receptor (67LR), which is expressed on high-grade tumor cells. An EGCG derivative was synthesized for binding to the end of PEG. Doxorubicin (DOX)-loaded EGCG-PEG-modified liposome (EPL) significantly decreased tumor size in mice bearing high 67LR-high-expressing tumors. Caspase-3 activity, which indicates induction of apoptosis, was also elevated only in the EPL group. The importance of PEG for the antitumor effects of EGCG was noted, as soluble EGCG did not accumulate at a sufficient concentration to exert an apoptotic effect. Moreover, EPL significantly increased caspase-8 activity, suggesting that EPL-induced apoptosis occurred due to caspase-8 activity induced following the binding of EGCG to 67LR as a cell-death ligand. In conclusion, EPL appear to have superior antitumor activity against high 67LR-expressing tumor cells, as the liposomes had dual effects, namely antitumor effects due to the loaded DOX and apoptosis induced by the bound EGCG.

Design of Tail-Clamp Peptide Nucleic Acid Tethered with Azobenzene Linker for Sequence-Specific Detection of Homopurine DNA.

DNA carries genetic information in its sequence of bases. Synthetic oligonucleotides that can sequence-specifically recognize a target gene sequence are a useful tool for regulating gene expression or detecting target genes. Among the many synthetic oligonucleotides, tail-clamp peptide nucleic acid (TC-PNA) offers advantages since it has two homopyrimidine PNA strands connected via a flexible ethylene glycol-type linker that can recognize complementary homopurine sequences via Watson-Crick and Hoogsteen base pairings and form thermally-stable PNA/PNA/DNA triplex structures. Here, we synthesized a series of TC-PNAs that can possess different lengths of azobenzene-containing linkers and studied their binding behaviours to homopurine single-stranded DNA. Introduction of azobenzene at the N-terminus amine of PNA increased the thermal stability of PNA-DNA duplexes. Further extension of the homopyrimidine PNA strand at the N-terminus of PNA-AZO further increased the binding stability of the PNA/DNA/PNA triplex to the target homopurine sequence; however, it induced TC-PNA/DNA/TC-PNA complex formation. Among these TC-PNAs, 9W5H-C4-AZO consisting of nine Watson-Crick bases and five Hoogsteen bases tethered with a beta-alanine conjugated azobenzene linker gave a stable 1:1 TC-PNA/ssDNA complex and exhibited good mismatch recognition. Our design for TC-PNA-AZO can be utilized for detecting homopurine sequences in various genes.

Substitution at the C-3 Position of Catechins Has an Influence on the Binding Affinities against Serum Albumin.

It is known that catechins interact with the tryptophan (Trp) residue at the drug-binding site of serum albumin. In this study, we used catechin derivatives to investigate which position of the catechin structure strongly influences the binding affinity against bovine serum albumin (BSA) and human serum albumin (HSA). A docking simulation showed that (-)-epigallocatechin gallate (EGCg) interacted with both Trp residues of BSA (one at drug-binding site I and the other on the molecular surface), mainly by π-π stacking. Fluorescence analysis showed that EGCg and substituted EGCg caused a red shift of the peak wavelength of Trp similarly to warfarin (a drug-binding site I-specific compound), while 3-O-acyl-catechins caused a blue shift. To evaluate the binding affinities, the quenching constants were determined by the Stern-Volmer equation. A gallate ester at the C-3 position increased the quenching constants of the catechins. Against BSA, acyl substitution increased the quenching constant proportionally to the carbon chain lengths of the acyl group, whereas methyl substitution decreased the quenching constant. Against HSA, neither acyl nor methyl substitution affected the quenching constant. In conclusion, substitution at the C-3 position of catechins has an important influence on the binding affinity against serum albumin.

A derivative of epigallocatechin-3-gallate induces apoptosis via SHP-1-mediated suppression of BCR-ABL and STAT3 signalling in chronic myelogenous leukaemia.

BACKGROUND AND PURPOSE: Epigallocatechin-3-gallate (EGCG) is a component of green tea known to have chemo-preventative effects on several cancers. However, EGCG has limited clinical application, which necessitates the development of a more effective EGCG prodrug as an anticancer agent. EXPERIMENTAL APPROACH: Derivatives of EGCG were evaluated for their stability and anti-tumour activity in human chronic myeloid leukaemia (CML) K562 and KBM5 cells. KEY RESULTS: EGCG-mono-palmitate (EGCG-MP) showed most prolonged stability compared with other EGCG derivatives. EGCG-MP exerted greater cytotoxicity and apoptosis in K562 and KBM5 cells than the other EGCG derivatives. EGCG-MP induced Src-homology 2 domain-containing tyrosine phosphatase 1 (SHP-1) leading decreased oncogenic protein BCR-ABL and STAT3 phosphorylation in CML cells, compared with treatment with EGCG. Furthermore, EGCG-MP reduced phosphorylation of STAT3 and survival genes in K562 cells, compared with EGCG. Conversely, depletion of SHP-1 or application of the tyrosine phosphatase inhibitor pervanadate blocked the ability of EGCG-MP to suppress phosphorylation of BCR-ABL and STAT3, and the expression of survival genes downstream of STAT3. In addition, EGCG-MP treatment more effectively suppressed tumour growth in BALB/c athymic nude mice compared with untreated controls or EGCG treatment. Immunohistochemistry revealed increased caspase 3 and SHP-1 activity and decreased phosphorylation of BCR-ABL in the EGCG-MP-treated group relative to that in the EGCG-treated group. CONCLUSIONS AND IMPLICATIONS: EGCG-MP induced SHP-1-mediated inhibition of BCR-ABL and STAT3 signalling in vitro and in vivo more effectively than EGCG. This derivative may be a potent chemotherapeutic agent for CML treatment.

Virus purification and enrichment by hydroxyapatite chromatography on a chip.

The spread of infectious diseases has become a global health concern. In order to diagnose infectious diseases quickly and accurately, next-generation DNA sequencing techniques for genetic analysis of infectious viruses have been developed rapidly. However, it takes a very long time to pretreat clinical samples for genetic analysis using next-generation sequencers. We have therefore developed a microfluidic chromatography chip that can purify and enrich viruses in a sample using hydroxyapatite particles packed in a micro-column. We demonstrated the purification of virus from a mixture of virus and FBS protein, and enrichment of the virus using this novel microfluidic chip.

Sequence-specific and visual identification of the influenza virus NS gene by azobenzene-tethered bis-peptide nucleic acid.

To rapidly and specifically identify highly virulent influenza virus strains, we prepared an azobenzene-tethered hairpin-type peptide nucleic acid, bisPNA-AZO, which has a complementary sequence against a highly conserved genomic RNA sequence within the ribonucleoprotein complex of the 2009 pandemic influenza A virus, H1N1 subtype. bisPNA-AZO recognizes the conserved virus genome sequence in a sequence-specific manner. Immobilization of bisPNA-AZO on a plate allowed capture of the target virus gene and the generation of a visual colour signal.

Label-free single-particle imaging of the influenza virus by objective-type total internal reflection dark-field microscopy.

Here we report label-free optical imaging of single particles of the influenza virus attached on a glass surface with a simple objective-type total internal reflection dark-field microscopy (TIRDFM). The capability of TIRDFM for the imaging of single viral particles was confirmed from fine correlation of the TIRDFM images with fluorescent immunostaining image and scanning electron microscopy image. The density of scattering spots in the TIRDFM images showed a good linearity against the virus concentration, giving the limit of detection as 1.2×10(4) plaque-forming units per milliliter. Our label-free optical imaging method does require neither elaborated sample preparation nor complex optical systems, offering a good platform for rapid and sensitive counting of viral particles.

Antibacterial and antifungal activities of new acylated derivatives of epigallocatechin gallate.

(-)-Epigallocatechin-3-O-gallate (EGCG) has useful antiviral, antimicrobial, antitoxin, and antitumor properties. Previously, Mori et al. (2008) found that addition of long acyl chains (C16-18) to EGCG enhanced its anti-influenza virus activity up to 44-fold. The chemical stability of EGCG against oxidative degradation was also enhanced by acylation. We further evaluated the in vitro activity spectrum of the EGCG derivatives against a wide range of bacteria and fungi. A series of EGCG O-acyl derivatives were synthesized by lipase-catalyzed transesterification. These derivatives exhibited several-fold higher activities than EGCG, particularly against Gram-positive organisms. Antifungal MICs of the derivatives were also two to fourfold lower than those of EGCG. The activities of the EGCG derivatives against Gram-negative bacteria were not distinguishable from those of EGCG. Among the derivatives evaluated, MICs of dioctanoate and palmitate (C16) for 17 Staphylococcus aureus strains were 4-32 µg/ml, although MIC of EGCG for these 17 strains was ≥128 µg/ml. C16 demonstrated rapid bactericidal activity against methicillin-resistant S. aureus (MRSA) ATCC43300 at ≥16 µg/ml. The enhanced activity of C16 against S. aureus was supported by its increased membrane-permeabilizing activity determined by increased SYTOX Green uptake. The EGCG derivatives were exported in Escherichia coli using the efflux pump AcrAB-TolC. The tolC deletion mutant exhibited higher sensitivity to EGCG and the derivatives than wild-type. Addition of long alkyl chains to EGCG significantly enhanced its activities against several bacteria and fungi, particularly against S. aureus including MRSA. C16 might potentially become under specified circumstances an alternative or supplement to antibiotics and disinfectants in the future.

Synthesis and application of visible light sensitive azobenzene.

Methods for regulating peptide conformation by non-harmful light stimuli can be useful for remotely controlling cellular functions in vitro. Here, we synthesized a series of p-heteroatom-substituted azobenzenes and studied their photoisomerization properties. The trans-isomer of p-sulfur-substituted azobenzene was effectively isomerized by visible light irradiation and the cis-isomer was thermally stable at physiological temperature. We developed a novel visible light sensitive amino acid (AZO), via p-sulfur-substituted azobenzene, and utilized it as a photosensitive modulator of the SV40 nuclear localization signal (NLS). The cellular uptake of the AZO-NLS conjugate was controlled by visible light irradiation. Our technology can be utilized for regulating not only the cellular uptake, but also the function of peptides within cells by non-harmful visible light irradiation.

Antioxidant and antiviral activities of silybin fatty acid conjugates.

Two selective acylation methods for silybin esterification with long-chain fatty acids were developed, yielding a series of silybin 7-O- and 23-O-acyl-derivatives of varying acyl chain lengths. These compounds were tested for their antioxidant (inhibition of lipid peroxidation and DPPH-scavenging) and anti-influenza virus activities. The acyl chain length is an important prerequisite for both biological activities, as they improved with increasing length of the acyl moiety.

Regulation of duplex DNA strand displacement by visible light sensitive bis-peptide nucleic acid.

A novel visible light sensitive azobenzene (AZO) was synthesized and introduced into bis-peptide nucleic acid (bis-PNA), which consists of two homopyrimidine PNA strands, as a linker. Visible light irradiation of the bis-PNA-AZO conjugate induced photoisomerization of the azobenzene moiety from trans to cis. The cis-form of bis-PNA-AZO displaced the complementary duplex DNA more efficiently than the trans-form.

Inhibition of influenza virus infection by targeting genome conserved region with non-natural nucleic acid.

Two highly conserved 15 base sequences of influenza A virus genome were identified by CONSERV software, which can detect contiguous conserved sequences of biological sequences. Antiviral effect of phosphorothioate oligonucleotide that target these conserved sequences was evaluated by plaque formation assay and cell viability assay. Pre-treatment of cells with anti-PB2 (RNA polymerase subunit) reduced the size of plaques in a sequence dependent manner. Post-treatment of cells with anti-PB2 phosphorothioate oligonucleotide inhibited the virus-induced cytotoxicity.

Enhanced antitumor activities of (-)-epigallocatechin-3-O-gallate fatty acid monoester derivatives in vitro and in vivo.

(-)-Epigallocatechin-3-O-gallate (EGCG) monoesters modified with butanoyl (EGCG-C4), octanoyl (EGCG-C8), palmitoyl groups (EGCG-C16) were synthesized by a lipase-catalyzed transesterification method and their antitumor activities were investigated in vitro and in vivo. The in vitro antitumor activities of EGCG-monoester derivatives increased in an alkyl chain length-dependent manner. The cytotoxicity of EGCG, EGCG-C4, EGCG-C8 was mainly caused by H(2)O(2) which was generated with their oxidation. On the other hand, EGCG-C16 was more stable than EGCG and it did not generate H(2)O(2) in the cell culture medium. Furthermore, EGCG-C16 inhibited cell proliferation and induced apoptosis in the presence of catalase. EGCG-C16 was found to inhibit the phosphorylation of the epidermal growth factor receptor (EGFR), which is related to various types of tumor growth. EGCG-C16 suppressed tumor growth in vivo in colorectal tumor bearing mice in comparison to an untreated control, vector control (DMSO) and EGCG.