Direct shoot regeneration from leaf explants of <Emphasis Type="Italic">Rosa damascena</Emphasis> Mill.

Summary A protocol for in vitro propagation using direct induction of shoot buds from leaf explants of in vitro-raised shoots of Rosa damascena var. Jwala is reported. The present study is the first report on direct shoot regeneration in scented roses. Elite plants raised from nodal explants and maintained for over 2yr in vitro on a static liquid shoot multiplication Murashige and Skoog (MS) medium supplemented with 5.0 μM benzyladenine (BA) and 3% sucrose were used. Petioles from fully developed young leaves, obtained after 4 wk of pruning of old shoots, were found to be ideal for regeneration of shoots. Initially the explants were cultured in an induction medium [half-strength MS+3% sucrose+6.8μM thidiazuron+0.27 μM α-naphthaleneacetic acid (NAA)+17.7 μM AgNO₃] and subsequently transferred to the regeneration medium (MS+2.25 μM BA+0.054 μM NAA) after 7, 14, 21, 28, and 35d. The highest shoot regeneration response (69%) was recorded when shoots were kept in the induction medium for 21 d and later transferred to regeneration medium. Histological studies revealed direct formation of shoot buds without the intervening callus phase. In vitro rooting of micro-shoots was accomplished within 2wk on half-strength MS liquid medium supplemented with 10.0 μM IBA and 3% sucrose for 1 wk in the dark and later transferred to hormone-free medium and kept in the light. Plantlets, remaining in the latter medium for 5–6 wk when transferred to soil, showed 90% survival.     

Intestinal mucins: the binding sites forsalmonella typhimurium

Mucus-bacterial interactions in the gastrointestinal tract and their impact on subsequent enteric infections are poorly delineated. In the present study, we have examined the binding ofSalmonella typhimurium to rat intestinal mucus and characterized a mucus protein (Mucus-Rs) which specifically binds to S. typhimurium. Both virulent (1402/84), and avirulent (SF 1835) S. typhimurium were observed to bind to crude mucus, however, the virulent strain showed 6 fold more binding as compared to avirulent strain. Fractionation of crude mucus on sepharose CL-6B resolved it into three major peaks. Maximal bacterial binding was observed with a high mol. wt. glycoprotein corresponding to neutral mucin. SDS-PAGE of purified protein (termed Mucus-Rs) under non reducing conditions showed it to be a homogenous glycoprotein (mol. wt. 250 kDa), while under reducing conditions, three bands corresponding to mol. wt. of 118,75 and 60 kDa were observed. Pretreatment of Mucus-Rs with pronase, trypsin and sodium metaperiodate markedly inhibited bacterial binding. GLC analysis of Mucus-Rs showed it to contain Mannose, Glucose, Galactose, Glucosamine, Galactosamine and Sialic acid as main sugars. Competitive binding in the presence of various sugars and lectins indicated the involvement of mannose in the mucus-bacterial interactions. The Mucus-Rs binding was highly specific for S. typhimurium; no significant binding was seen with E.coliand V. cholerae. Thus, we conclude that S. typhimurium specifically binds to a 250 kDa neutral mucin of intestinal tract. This binding appears to occur via specific adhesin-receptor interactions involving bacterial pili and mannose of neutral mucin.     

Cross-Protective Effect of Antisense Oligonucleotide Developed Against the Common 3′ NCR of Influenza A Virus Genome

The influenza A virus (IAV) has eight segmented single-stranded RNA genome containing a common and evolutionarily conserved non-coding region (NCRs) at 5′ and 3′ ends that are important for the virus replication. In this study, we designed an antisense oligonucleotide against the 3′ NCR of vital segments of the IAV genome to inhibit its replication. The results demonstrated that the co-transfection of Madine Darby Canine Kidney (MDCK) cells with the antisense oligonucleotide and the plasmids encoding the viral genes led to the down-regulation of the viral gene expression. The designed antisense molecules reduced the cytopathic effect caused by A/PR/8/34 (H1N1), A/Udorn/307/72 (H3N2), and A/New Caledonia/20/99 (H1N1) strains of IAV for almost 48 h. Furthermore, the intra-venous delivery of this oligonucleotide significantly reduced the viral titers in the lungs of infected mice and protected the mice from lethal effects of all the strains of influenza virus. The study demonstrated that the antisense oligonucleotide designed against the NCR region inhibits the expression of the viral genome. The decrease of the cytopathic effect in the MDCK cells and increase in survival of mice confirmed the reduction of virus multiplication and pathogenesis in the presence of antisense oligonucleotide. Thus, we demonstrate that a single antisense oligonucleotide is capable of providing protection against more than one strains of the IAV.     

Classification of Rice Seed Storage Proteins using Neural Networks

Bioinformatics techniques are increasingly employed in annotation of information from sequencing of model organisms. Development of rice varieties with improved protein quality requires detailed annotation and classification of seed storage proteins in rice germplasm. Two neural network tools were employed for classification of seed storage proteins into four classes- Albumins, Globulins, Gluteins and Prolamins using biochemical, structural properties and conserved sequence patterns. Protein classification results obtained from two software tools were cross compared and superior protein family classification accuracy of 95.3 percent is achieved with Alyuda Neurointelligence computational tool. This is the first report on classification of rice seed proteins using sequenced rice genome information.     

Expression of 3-hydroxy-3-methylglutaryl-CoA reductase, p-hydroxybenzoate-m-geranyltransferase and genes of phenylpropanoid pathway exhibits positive correlation with shikonins content in arnebia [Arnebia euchroma (Royle) Johnston]

Background

Formation of site specific genomic double strand breaks (DSBs), induced by the expression of a pair of engineered zinc-finger nucleases (ZFNs), dramatically increases the rates of homologous recombination (HR) between a specific genomic target and a donor plasmid. However, for the safe use of ZFN induced HR in practical applications, possible adverse effects of the technology such as cytotoxicity and genotoxicity need to be well understood. In this work, off-target activity of a pair of ZFNs has been examined by measuring the ratio between HR and illegitimate genomic integration in cells that are growing exponentially, and in cells that have been arrested in the G2/M phase.

Results

A reporter cell line that contained consensus ZFN binding sites in an enhanced green fluorescent protein (EGFP) reporter gene was used to measure ratios between HR and non-homologous integration of a plasmid template. Both in human cells (HEK 293) containing the consensus ZFN binding sites and in cells lacking the ZFN binding sites, a 3.5 fold increase in the level of illegitimate integration was observed upon ZFN expression. Since the reporter gene containing the consensus ZFN target sites was found to be intact in cells where illegitimate integration had occurred, increased rates of illegitimate integration most likely resulted from the formation of off-target genomic DSBs. Additionally, in a fraction of the ZFN treated cells the co-occurrence of both specific HR and illegitimate integration was observed. As a mean to minimize unspecific effects, cell cycle manipulation of the target cells by induction of a transient G2/M cell cycle arrest was shown to stimulate the activity of HR while having little effect on the levels of illegitimate integration, thus resulting in a nearly eight fold increase in the ratio between the two processes.

Conclusions

The demonstration that ZFN expression, in addition to stimulating specific gene targeting by HR, leads to increased rates of illegitimate integration emphasizes the importance of careful characterization of ZFN treated cells. In order to reduce off-target events, reversible cell cycle arrest of the target cells in the G2/M phase is an efficient way for increasing the ratio between specific HR and illegitimate integration.     

The N-terminal epidermal growth factor-like domain in factor IX and factor X represents an important recognition motif for binding to tissue factor.

Factors VII, IX, and X play key roles in blood coagulation. Each protein contains an N-terminal gamma-carboxyglutamic acid domain, followed by EGF1 and EGF2 domains, and the C-terminal serine protease domain. Protein C has similar domain structure and functions as an anticoagulant. During physiologic clotting, the factor VIIa-tissue factor (FVIIa*TF) complex activates both factor IX (FIX) and factor X (FX). FVIIa represents the enzyme, and TF represents the membrane-bound cofactor for this reaction. The substrates FIX and FX may utilize multiple domains in binding to the FVIIa*TF complex. To investigate the role of the EGF1 domain in this context, we expressed wild type FIX (FIX(WT)), FIX(Q50P), FIX(PCEGF1) (EGF1 domain replaced with that of protein C), FIX(DeltaEGF1) (EGF1 domain deleted), FX(WT), and FX(PCEGF1). Complexes of FVIIa with TF as well as with soluble TF (sTF) lacking the transmembrane region were prepared, and activations of WT and mutant proteins were monitored by SDS-PAGE and by enzyme assays. FVIIa*TF or FVIIa*sTF activated each mutant significantly more slowly than the FIX(WT) or FX(WT). Importantly, in ligand blot assays, FIX(WT) and FX(WT) bound to sTF, whereas mutants did not; however, all mutants and WT proteins bound to FVIIa. Further experiments revealed that the affinity of the mutants for sTF was reduced 3-10-fold and that the synthetic EGF1 domain (of FIX) inhibited FIX binding to sTF with K(i) of approximately 60 microm. Notably, each FIXa or FXa mutant activated FVII and bound to antithrombin, normally indicating correct folding of each protein. In additional experiments, FIXa with or without FVIIIa activated FX(WT) and FX(PCEGF1) normally, which is interpreted to mean that the EGF1 domain of FX does not play a significant role in its interaction with FVIIIa. Cumulatively, our data reveal that substrates FIX and FX in addition to interacting with FVIIa (enzyme) interact with TF (cofactor) using, in part, the EGF1 domain.     

UV-B radiation and temperature stress-induced alterations in metabolic events and defense mechanisms in a bloom-forming cyanobacterium <Emphasis Type="Italic">Microcystis aeruginosa</Emphasis>

The present investigation is aimed to understand how a bloom-forming cyanobacterium Microcystis aeruginosa adapts to changing climatic conditions. The cyanobacterium was exposed to stresses of UV-B (2 Wm^?2) radiation and temperature (45 °C) for desired time intervals. Results showed that both the stresses affect growth and photosynthetic efficiency of M. aeruginosa. More than 50% loss of survival and content of photosynthetic pigments was noted after 4 h treatment of both the above stresses. Such changes were mainly due to the generation of reactive oxygen species which cause damage to proteins, DNA, lipids, and modulation of the membrane stability. An increase in the proline accumulation was noted in the cells which probably negates the harmful effects. In addition, activity of antioxidative enzymes namely, catalase, superoxide dismutase, ascorbate peroxidase, and peroxidase was induced by 1.5–3.0-fold on 3 h of UV-B and temperature treatment indicating their possible role in protection. Interestingly, induction of photoprotective compound, mycosporine-like amino acids (MAAs) were also found under UV-B stress which might be an additional strategy of defense mechanism for the survival of the cyanobacterium. Analysis of photoprotective compound revealed shinorine as the main MAA synthesized by the cyanobacterium.     

Positive selection vectors for high-fidelity PCR cloning

The power of PCR cloning of a target DNA fragment is limited by polymerase-induced mutations. While high-fidelity PCR products can be achieved by reducing the number of PCR cycles, the cloning of the very small amount of DNA thus amplified should give only a few recombinant clones (carrying an insert), which would be very difficult to screen from thousands of background false-positive clones generated by all the currently available vectors, including the positive selection vectors. False-positive clones are mostly generated by the recircularization of linearized vectors that have lost some bases at their ends due to digestion with contaminating exonuclease activities present in restriction enzymes, ligases, polymerases, and other reagents. To overcome this problem, two positive selection vectors, pRGR1Ap and pREM5Tc, have been developed, based on the principles of reporter gene reconstruction and regulatory element modulation, respectively. A PCR primer carrying a vector-specific sequence at its 5' end is used in PCR. When the resultant PCR products are ligated to the specific vector, an antibiotic resistance gene is expressed, thus donating positive selection capability to the harboring cells in a specific selection medium. These vectors cloned PCR fragments generated from less than a femtomole quantity of Escherichia coli genomic DNA after only three cycles of PCR amplification, thus greatly reducing the number of recombinant clones containing polymerase-induced mutations.