TRICORE, a novel bead-based specimen concentration method for the culturing of Mycobacterium tuberculosis.

Centrifugation is a necessary concentrating step for the detection of Mycobacterium tuberculosis in a liquid culture. However, centrifugation is biologically hazardous and presents an obstacle in the development of an automated culture system. A bead-based bacterial concentration method, TRICORE, was recently developed by Genetein Co., Ltd. We compared the efficacy of TRICORE and conventional centrifugation for concentrating M. tuberculosis in clinical sputum specimens by using liquid and solid culture systems. Among 90 pretreated clinical sputum specimens, 51 (57.3%) and 55 (61.8%) M. tuberculosis isolates were recovered by the MGIT culture system by using the centrifugation and TRICORE methods, respectively (chi-square test, p=0.5413). The detection time for the centrifugation method was 359.3±117.0 h, while that for the bead-based concentration method was 377.6±162.3 h (p=0.5637). However, the number of colonies recovered on solid media were significantly higher with the TRICORE method (p=0.003). In particular, among the smear-negative specimens, culture positivity of the TRICORE method was 39.6%, while that of the centrifugation method was 15.1%. The TRICORE bead-based concentration method was considered equivalent to centrifugation and enabled efficient collection of paucibacillary specimens in solution. Thus, the new noncentrifugation concentration method could yield more positive culture results.

Galactose-PEG dual conjugation of beta-(1-->3)-D-glucan schizophyllan for antisense oligonucleotides delivery to enhance the cellular uptake.

Antisense oligonucleotides (AS ODNs) are applied to silence a particular gene, and this approach is one of the potential gene therapies. However, naked oligonucleotides are easy to be degraded or absorbed in biological condition. Therefore, we need a carrier to deliver AS ODNs. This paper presents galactose moieties that were conjugated to the side chain of SPG to enhance cellular ingestion through endocytosis mediated by asialoglycoprotein receptor specifically located on parenchymal liver cells. We introduced galactose with two types of chemical bonds; amide and amine, and the amine connection showed lower ingestion and more toxicity than the amide one. Since PEG was known to induce endocytosis escape, we combined PEG and galactose aiming to provide both cellular up-take and subsequent endocytosis escape. We designed lactose or galactose moieties to attach to the end of the PEG chain that connects to the SPG side chain. When the PEG had the molecular weight of 5000-6000, the antisense effect reached the maximum. We believe that this new type of galactose and PEG dual conjugation broaden the horizon in antisense delivery.

CpG DNA/zymosan complex to enhance cytokine secretion owing to the cocktail effect.

Zymosan, classified among beta-(1-->3)-d-glucans, is produced from the cell wall of yeast and well known to induce proinflammatory cytokines when ingested by immune cells. We found that zymosan forms a complex with immunostimulatory CpG DNA, where both zymosan and CpG DNA can induce cytokine secretion according to the different mechanisms (i.e., recognized by different receptors). The complex activated macrophages and induced cytokine secretion, more efficiently than separate administration of zymosan or CpG DNA. Microscopic observation showed that this increment of the cytokine secretion can be explained by the fact that zymosan and zymosan/CpG DNA complex are up-taken more than naked CpG DNA. Additionally, existence of two different immunostimulants in the same cells may enhance the immunoresponse. This report presents a new strategy to construct a delivering vehicle for CpG DNA and to enhance its activity with the 'cocktail effect' of the two immunostimulants.

Transition from a normal to inverted cylinder for an amidine-bearing lipid/pDNA complex and its excellent transfection.

A cationic lipid (TRX) having an amidine headgroup was synthesized, and a lipoplex (i.e., plasmid DNA+lipid complex) was prepared from the mixture of TRX and two other neutral colipids. Small-angle X-ray scattering showed that the addition of DNA induced a structural transition from normal to inverted hexagonally packed cylinders. Transmission electron microscopy showed a threadlike micelle was transformed to a spherical micelle about 50-200 nm in diameter by adding DNA. A combination of these results leads to the conclusion that the complexed DNA is hexagonally packed (or condensed) into spherical aggregates. The size and morphology are believed suitable for endocytosis uptake or vesicle fusion. The complex made from pDNA (pEGFP-C1) and TRX was transfected to Hep G2. Flow cytometry and confocal microscopy showed that the present system expressed green fluorescence protein (GFP) more than a conventional transfection reagent. Additionally, TRX was less cytotoxic than other transfection reagents. This paper presents the attractive possibility of the amidine group for a transfection device.

Linear double-stranded DNA that mimics an infective tail of virus genome to enhance transfection.

Our previous work showed that a natural beta-(1-->3)-d-glucan schizophyllan (SPG) can form a stable complex with single-stranded oligonucleotides (ssODNs). When protein transduction peptides were attached to SPG and this modified SPG was complexed with ssODNs, the resultant complex could induce cellular transfection of the bound ODNs, without producing serious cytotoxicity. However, no technique was available to transfect double-stranded DNAs (dsDNA) or plasmid DNA using SPG. This paper presents a new approach to transfect dsDNA, showing preparation and transfection efficiency for a minimal-size gene having a loop-shaped poly(dA)(80) on both ends. This poly(dA) loops of dsDNA can form a complex with SPG. An siRNA-coding dsDNA with the poly(dA) loop was complexed with Tat-attached SPG to silence luciferase expression. When LTR-Luc-HeLa cells that can express luciferase under the control of the LTR promoter were exposed to this complex, the expression of luciferase was suppressed (i.e., RNAi effect was enhanced). Cytotoxicity studies showed that the Tat-SPG complex induced much less cell death compared to polyethylenimine, indicating that the proposed method caused less harm than the conventional method. The Tat-SPG/poly(dA) looped dsDNA complex had a structure similar to the viral genome in that the dsDNA ends were able to induce transfection and protection. The present work identifies the SPG and poly(dA) looped minimum-sized gene combination as a candidate for a non-toxic gene delivery system.

Inclusion of DNA into organic gelator fibers made of amphipathic molecules and its controlled release.

When methyl 4,6-O-(p-nitrobenzylidene)-alpha-D-glucopyranoside (p-NO(2)Glu) was dissolved in water, p-NO(2)Glu molecules self-assembled to form a fiber (elemental fiber), and as a result, the solution became a partially transparent gel. When an equal (or more) amount of DNA was added to the gel, a white and crystalline gel was obtained. Energy-dispersive X-ray spectroscopy coupled with TEM and confocal microscopy suggested that DNA was included in the gel fibers made of p-NO(2)Glu molecules. The results imply that p-NO(2)Glu molecules are self-assembled to form an elemental fiber and these elemental fibers and DNA are twisted together to form higher hierarchic fibers. When the complexed gel made of plasmid DNA (pDNA) and p-NO(2)Glu was added to E. coli T7 S30 extract solution, the pDNA had less expression ability compared with naked one. When we added methyl-beta-cyclodextrin (MbetaCyD), the expression rate was recovered with increasing added amount of MbetaCyD. The present paper shows inclusion and controlled release of DNA from a novel supporting material of DNA and that technology could play an important role in the development of localized approaches to gene therapy.

PEG-appended beta-(1-->3)-D-glucan schizophyllan to deliver antisense-oligonucleotides with avoiding lysosomal degradation.

Schizophyllan is a natural beta-(1-->3)-d-glucan existing as a triple helix in water and as a single chain in dimethylsulfoxide (DMSO). As we already reported, when a homo-polynucleotide [e.g., poly(dA) or poly(C)] is added to the schizophyllan/DMSO solution and subsequently DMSO is exchanged for water, the single chain of schizophyllan forms a complex with the polynucleotide. One of the potential applications for this novel complex is an antisense-oligonucleotide (AS ODN) carrier. The present paper describes a modification technique that enabled us to introduce PEG only to the side chain of schizophyllan. This technique consisted of periodate oxidation of the glucose side chain and subsequent reaction between methoxypolyethylene glycol amine and the formyl terminate, followed by reduction with NaBH4. Subsequently, we made a complex from PEG-appended schizophyllan and an AS ODN sequence, and carried out an in vitro antisense assay, administrating the AS ODN complex to depress A375 c-myb mRNA of A375 melanoma cell lines. The PEG-SPG/AS ODN complex showed more enhanced antisnese effect than naked AS ODN dose, i.e., the same level as that of RGD-appended SPG. Here, the RGD system has been shown one on the most effective AS ODN carrier (Science 261 (1993) 1004-1012). When we added nigericin to the assay system, the antisense effect was not affected in the PEG-SPG system, on the other hand, it was almost eliminated in the RGD system. Nigericin is well known to interrupt transport from endosome to lysosome. Therefore, the difference between the PEG and RGD complexes indicates that, in the PEG system, AS ODN was able to escape from lysosomal degradation. The present work has thus proposed a new strategy to delivery AS ODN using schizophyllan as a new carrier.

Schizophyllan-folate conjugate as a new non-cytotoxic and cancer-targeted antisense carrier.

Schizophyllan having folate-appendages was synthesized from native schizophyllan through NaIO(4)-oxidation and the subsequent reductive amination in aqueous ammonia followed by amido-coupling with folic acid. The resulting folate-appended schizophyllan can form stable complex with poly(dA), show specific affinity toward folate binding protein, and mediate effective antisense activity in cancer cells.

Schizophyllans carrying oligosaccharide appendages as potential candidates for cell-targeted antisense carrier.

Schizophyllans carrying beta-lactoside and alpha-mannoside appendages were prepared from native schizophyllan through NaIO4 oxidation followed by reductive amination using aminoethyl-beta-lactoside and alpha-mannoside, respectively. The resulting schizophyllans form stable macromolecular complexes with polynucleotides, such as poly(C) and poly(dA). Specific affinity between these macromolecular complexes and saccharide-binding proteins was demonstrated by surface plasmon resonance and agarose gel staining assays. beta-lactoside-appended schizophyllan enhanced an antisense activity in hepatocytes which express lactoside-binding proteins on their cell surfaces.

Proposal of new modification technique for linear double-stranded DNAs using the polysaccharide schizopyllan.

A natural polysaccharide schizophyllan (SPG) has been known to form a stable complex with poly(dA). We attached a poly(dA)(80) tail to the both ends of a linear double-stranded DNA, which had been prepared from a plasmid DNA vector. The poly(dA) tailed DNA verified to form complex with SPG by gel electrophoresis and atomic force microscopy (AFM). AFM images indicated that the complexes exhibit a dumbbell-like architecture, that is, quite similar to that of adenovirus genome. The complex demonstrated excellent exonuclease resistance, probably because of the protection effect by SPG complexation.

Removal of the side-chain glucose groups from schizophyllan improves the thermal stability of the polycytidylic acid complexes under the physiological conditions.

Thermal stabilization of the complex between polycytidylic acid [poly(C)] and the modified schizophyllan (SPG) whose hydrophilic side-chain glucose groups are selectively removed utilizing mild Smith-degradation has been investigated. With the decrease in the side-chain glucose groups of schizophyllan, the complex with poly(C) can be considerably stabilized compared with unmodified SPG; for example, the T(m) value after the removal of the side-chain glucose groups from 33.3 (unmodified) to 1.0 is enhanced by 14 degrees C. In addition, the thermal stabilization effect is even operative under the physiological conditions ([NaCl] = 0.15 mol dm(-3)). This effect is exerted owing to the construction of the hydrophobic atmosphere around the complex. Although schizophyllan lost the side-chain glucose groups, it still kept the protection effect of the bound poly(C) chain against RNaseA-mediated hydrolysis as observed for unmodified schizophyllan. The assessment of the cytotoxicity for A375:human malignant melanoma, and HL60:human promyelocytic leukemia revealed that the modified schizophyllan scarcely increases the cytotoxicity. These results indicate that the present modification for schizophyllan is of great significance in a viewpoint to develop the practical gene carriers operative even under the physiological conditions.

First observation by fluorescence polarization of complexation between mRNA and the natural polysaccharide schizophyllan.

Schizophyllan is a natural beta-(1-->3)-D-glucan that exists as a triple helix in H(2)O and as a single chain in dimethylsulfoxide (DMSO) or basic solution (pH >13). As we have already reported, when a homo-polynucleotide (e.g., poly(dA), poly(A), or poly(C)) is added to a schizophyllan/DMSO solution, and, subsequently, DMSO is exchanged for H(2)O, the single chain of schizophyllan forms a complex with the polynucleotide. Since eukaryotic mRNAs have poly(A) tails, we hypothesized that schizophyllan can bind to mRNA by interacting with this tail. However, we have not yet observed complexation between schizophyllan and mRNA after exchanging DMSO for H(2)O. In this report, we show that the complexation can be accelerated when the solution pH is changed from 13 to 7-8 in the presence of schizophyllan and polynucleotides. By this approach, we found that schizophyllan forms a complex with a yeast mRNA.

Microanalysis of nucleic acids using the limulus G test.

The limulus G test has been used as a quantitative analysis of (1-->3)-beta-D-glucans, including schizophyllan (SPG) and curdlan. The present work extended the limulus G test to detect polynucleotide/SPG complexes. The complex showed an extremely sensitive response to the test, compared with SPG itself. The minimum concentration of the complex to show the response is almost 10-times as small as that of SPG itself, indicating the possibility to detect (1-->3)-beta-D-glucans or/and polynucleotides on the pico gram/ml scale.