<Emphasis Type="Italic">Malvastrum yellow vein virus</Emphasis>, a new<Emphasis Type="Italic">Begomovirus</Emphasis> species associated with satellite DNA molecule

Virus isolate Y47 was obtained fromMalvastrum coromandelianum showing yellow vein symptom in Honghe, Yunnan Province. The complete nucleotide sequence of DNA-A was determined, it contains 2731 nucleotides, having typical genomic organization of a begomovirus, encoding 6 ORFs with 2 ORFs [AV1(CP) and AV2] in virionsense DNA and 4 ORFs (AC1–AC4) in complementarysense DNA. Comparisons show that the total DNA-A of Y47 has the highest sequence identity (77%) with that ofOkra yellow vein mosaic virus- [201] (AJ002451), while less than 76% identities are found when compared with other begomoviruses. The molecular data show that virus isolate Y47 is a distinct begomovirus species, for which the nameMalvastrum yellow vein virus is proposed. Satellite DNA molecule (Y47β) was found to be associated with Y47 using the primers (beta01 and beta02) specific for DNAβ. Y47β consists of 1348 nucleotides, with a functional ORF (C1) in complementary-sense DNA. Y47β has 62%–67% sequence identity with DNAβ molecule associated withCotton leaf curl Multan virus orCotton leaf curl Rajasthan virus, while lower than 46% sequence identities are found when compared with other reported DNAβ molecules. Relationship dendrograms show that DNAβ molecules are co-evolved with their help begomoviruses.     

Molecular characterization of<Emphasis Type="Italic">Tomato yellow leaf curl China</Emphasis> virus and its satellite DNA isolated from tobacco

Virus isolates, Y8, Y36 and Y38, were obtained from tobacco plants showing leaf curl symptoms in Honghe,Yunnan Province. In reactions with 14 monoclonal antibodies raised against Begomoviras particles, Y8, Y36 and Y38 had similar antigenic reaction in TAS-ELISA as Tomato yellow leaf carl China virus (TYLCCNV). The complete DNA-A nueleotide sequences of Y8, Y36 and Y38 were determined and they contain 2727, 2730 and 2730 nueleotides, respectively. Each of the DNA-A sequences has a typical Begomovirus genome organization encoding 60RFs with 20RFs[AVI(CP) and AV2] in virion-sense DNA and 40RFs (AC1 to AC4) in complementary-sense DNA. Comparisons with total DNA-A, intergenie region and deduced amino acid sequences of individual ORFs show that Y8, Y36 and Y38 are isolates of TYLCCNV. Satellite DNA molecules (DNAβ) were found to be associated with Y8, Y36 and Y38, which consist of 1338, 1339 and 1338 nucleotides, respectively. Comparisons show that these DNAβ molecules share 98%--99% sequence identities on nucleotide level and have a common ORF (designated C1) encoding 126 amino acids on the complementary strand.     

Function of A-Rich region in DNAβ associated with Tomato yellow leaf curl China virus

A novel type of circular single-stranded satellite DNA, known as DNAβ, was recently characterized and demonstrated to be associated with monopartite begomoviruses. DNAβ was essential for induction of characteristic symptoms in plants. DNAβ has three structural features: an 115 bp highly conserved region, tiC/gene and A-Rich region. The in-frame ATG mutation of βC1 gene of Tomato yellow leaf curl China virus isolate Y10 (TYLCCNV-TY10) DNAβ demonstrated that βC1 gene is required for leaf curl symptom. Here, the function of A-Rich region in TYLCCNV-Y10 DNAβ was identified. When A-Rich region was deleted, the A-Rich deleted mutant was still capable of replication and systemic infection in plant, indicating that A-Rich region is not required for trans-replication of DNAβ. The immunotrapping-PCR demonstrated that A-Rich deleted mutant could be encapsidated in the coat protein encoded by TYLCCNV-Y10 DNA-A, suggesting that A-Rich region is not related with DNAβ encapsidation. However, the A-Rich region deleted mutant caused milder symptom.     

Southern rice black-streaked dwarf virus: A new proposed <Emphasis Type="Italic">Fijivirus</Emphasis> species in the family <Emphasis Type="Italic">Reoviridae</Emphasis>

For the past several years, a novel dwarf disease has been observed on rice （Oryza sativa） in some regions of Guangdong Province and Hainan Province, southern China. Infected plants showed stunting, dark leaf and small enations on stem and leaf back. Typical Fijivirus viroplasma containing crystalline arrayed spherical virons approximately 70--75 nm in diameter and tubular structures were detected in ultrathin sections by an electron microscope in parenchyma phloem cells of the infected plants. The virus was transmitted to rice seedlings by white-backed planthoppers, Sogatella furcifera （Hemiptera： Delphacidae）, collected in the diseased fields. Analysis of dsRNA extracts from infected plants revealed ten linear segments, which were similar to the electrophoretic profile of Rice black-streaked dwarf virus （RBSDV）. RT-PCR with a single primer which matched to a linker sequence ligated to both 3＇ ends of the viral genomic dsRNAs resulted in amplification of genome segments 9 （S9） and 10 （S10） cDNA products. The complete nucleotide sequences of S9 and S10 were obtained from clones of the RT-PCR amplicon exhibited characteristic properties of Fijivirus including low GC content （34.5% and 35.6%）, genus conserved 5＇ and 3＇ termini sequences and similar genome organization. Blast searches indicated that the sequences of S9 and S10 shared 68.8%--74.9% and 67.1% --77.4% nucleotide identities with those of viruses in the Fijivirus group 2, respectively. These values were similar to those among other viruses in the Fijivirus group 2 and considerably lower than those among RBSDV isolates. Phylogenetic trees based on S9 and S10 nucleotide sequences and their putative amino acid sequences showed that this virus represented a separate branch among other Fijiviruses. The virus was also detected by a nested RT-PCR assay in corn （Zea mays）, barnyard grass （Echinochloa crusgalll）, Juncellus serotinus and flaccidgrass （Pennisetum flaccidum） in and/or adjacent to the infected rice fields. I     

Knockdown of <Emphasis Type="Italic">MRP4</Emphasis> by lentivirus-mediated siRNA improves sensitivity to adriamycin in adriamycin-resistant acute myeloid leukemia cells

Chemotherapy remains the standard treatment for acute myeloid leukemia;however,the emergence of drug resistance is a major hurdle in the successful treatment of leukemia.The expression of multidrug resistance-associated protein 4(MRP4)induces re- sistance in the adriamycin-resistant acute myeloid leukemia cell line,K562/ADR.The aim of this study was to investigate whether knockdown of MRP4 by lentivirus-mediated siRNA could improve the sensitivity of K562/ADR cells to adriamycin.Five lenti- virus-mediated short hairpin RNAs(lv-shRNAs-MRP4)were designed to trigger the gene silencing RNA interference(RNAi) pathway.The efficiency of lentivirus-mediated siRNA infection into K562/ADR cells was determined using fluorescence mi- croscopy to observe lentivirus-mediated GFP expression.MRP4 expression in infected K562/ADR cells was evaluated by real- time PCR and Western blot analysis.The MTS assay was used to measure cell viability and flow cytometry was used to measure apoptosis.The transfection efficiency of K562/ADR cells was over 80 percent.The gene silencing efficacy of lv-shRNA1-MRP4 was superior to the other constructs.Infection of K562/ADR cells with lv-shRNA1-MRP4 led to strong inhibition of MRP4 mRNA and protein expression.Combined treatment with lv-shRNA1-MRP4 and adriamycin decreased cell growth and increased apoptosis compared to treatment with lv-shRNA1-MRP4 or adriamycin alone.These data indicate that in K562/ADR cells MRP4 is involved in drug resistance mechanisms and that lentivirus-mediated knockdown of MRP4 may enhance sensitivity to adriamycin.     

Cloning and expression of <Emphasis Type="Italic">AtPLC6</Emphasis>, a gene encoding a phosphatidylinositol-specific phospholipase C in <Emphasis Type="Italic">Arabidopsis thaliana</Emphasis>

A full-length cDNA clone corresponding to a putative phosphatidylinositol-specific phospholipase C(PIPLC) was isolated from Arabidopsis thaliana by screening a cDNA library and using RT-PCR strategy.The cDNA,designated AtPLC6,encodes a putative polypeptide of 578 amino acid residues with a calculated molecular mass of 66251.84 D and a pI of 7.24. The sequence analysis indicates that the polypeptide contains X, Y, EF-hand and C2 domains.The overall structure of putative AtPLC6 protein, like other plant PI-PLCs,is most similar to that of mammalian PLCδ The recombinant AtPLC6 protein expressed in E. coil was able to hydrolyze phosphatidylinositol 4,5-biophosphate (PIP2) to generate inositol 1,4,5-trisphate (IP3) and 1,2-diacylglycerol (DAG).The protein hydrolyzes PIP2 in a Ca^2 -dependent manner and the optimum concentration of Ca^2 is 10μmol/L.These results suggested that AtPLC6 gene encodes a genuine PIPLC.Northern blot analysis showed that the AtPLC6 gene is expressed at low level in all examined tissues, such as roots,stems,leaves,flowers,siliques and seedlings under normal growth conditions.The gene is strongly induced under low temperature and weakly induced under various stresses,such as ABA, high-salt stress and heat. These results suggested that AtPLC6 might be involved in the signal-transduction pathways of cold responses of the plants.     

Agrobacterium tumefaciens-mediated Transformation of CryⅠA(b) gene to Trichoderma harzianum

In this study, Cry ⅠA(b) gene was successfully transferred into the biocontrol fungus Trichoderma harzianum with an efficiency of 60-180 transformants per 10^6 spores by using Agrobacterium tumefaciens-mediated transformation. Putative transformants were analyzed to test the presence of Cry ⅠA(b) gene by Southern blot. Most transformants contained a single T-DNA copy. RT-PCR analysis showed that the Cry ⅠA(b) gene was transcribed. Antifungal activities and insecticidal activities of the transformants were examined. There was no obvious difference in antifungal activities between the transformants and their wild strains. The modified mortalities of the transformants T1 and T2 were 69.57% and 91.30%, respectively. The tranformation system mediated by A. tumefaciens proved to be a powerful tool for the filamentous fungi transformation and functional genomic study with its high transformation frequency, simplicity of T-DNA integration, and genetic stability of transformants.     

Genetic analysis and gene fine mapping of a rolling leaf mutant (<Emphasis Type="Italic">rl</Emphasis><Subscript><Emphasis Type="Italic">11(t)</Emphasis></Subscript>) in rice (<Emphasis Type="Italic">Oryza sativa</Emphasis> L.)

The exploration of new genes controlling rice leaf shape is an important foundation for rice functional genomics and plant archi-tecture improvement. In the present study, we identified a rolling leaf mutant from indica variety Yuefeng B, named rl_11(t), which exhibited reduced plant height, rolling and narrow leaves. Leaves in rl_11(t) mutant showed abnormal number and morphology of veins compared with those in wild type plants. In addition, rl_11(t) mutant was less sensitive to the inhibitory effect of auxin than the wild type. Genetic analysis suggested that the mutant was controlled by a single recessive gene. Gene Rl_11(t) was initially mapped between SSR markers RM6089 and RM124 on chromosome 4. Thirty-two new STS markers around the Rl_11(t) region were developed for fine mapping. A physical map encompassing the Rl_11(t) locus was constructed and the target gene was finally delimited to a 31.6 kb window between STS4-25 and STS4-26 on BAC AL606645. This provides useful information for cloning of Rl_11(t) gene.     

Biologically active <Emphasis Type="Italic">cis</Emphasis>-cinnamic acid occurs naturally in <Emphasis Type="Italic">Brassica parachinensis</Emphasis>

The biologically active cis-cinnamic acid (cis-CA) has been perceived as a synthetic plant growth regulator for decades,However,in the present study,we found that cis-CA actually exists as a naturally occurring compound in a Brassica plant,This natural growth-regulating substance presents in both the sunlight-irradiated leaf tissue and the non-irradiated root tissue ,The concentrations of cis-CA in both tissues are comparable to the bilogi-cally effective lvels of those major plant hormones,the presence of cis-CA in root tissue suggests that it may be produced through both light-dependent and -independent path-ways or it can be transproted from a plant organ to another.     

Mechanism of <Emphasis Type="Italic">Aulacophora femoralis chinensis</Emphasis> Weise feeding behavior and chemical response of host <Emphasis Type="Italic">Cucumis sativus</Emphasis> L.

One of the frontiers in ecological study is the inter-action between plant and insect mediated by secondary metabolites[1]. Recent studies on the chemical interactions in the food chain of crop-pest-natural enemy showed that insects have olfactory response to the volatile al-lelochemicals released from plants[2,3]. Insects could in-teract with plants through their vision, olfaction and taste, and taste could be the most direct response mechanism of their herbivory. Some beetles (Acalymma, Aul…     

Proteomic analysis of long-term salinity stress-responsive proteins in <Emphasis Type="Italic">Thellungiella halophila</Emphasis> leaves

Salinity is one of the most severe environmental factors that may impair crop productivity. A proteomic study based on two-dimensional gel electrophoresis is performed in order to analyze the long-term salinity stress response of Thellungiella halophila, an Arabidopsis-related halophyte. Four-week-old seedlings are exposed to long-term salinity treatment. The total crude proteins are extracted from leaf blades, separated by 2-DE, stained with Coomassie Brilliant Blue, and differentially displayed spots are identified by MALDI-TOF MS or QTOF MS/MS. Among 900 protein spots reproducibly detected on each gel, 30 spots exhibit significant change and some of them are identified. The identified proteins include not only some previously characterized stress-responsive proteins such as TIR-NBS-LRR class disease resistance protein, ferritin-1, and pathogenesis-related protein 5, but also some proteins related to energy pathway, metabolism, RNA processing and protein degradation, as well as proteins with unknown functions. The possible functions of these proteins in salinity tolerance of T. halophila are discussed and it is suggested that the long-term salinity tolerance of T. halophila is achieved, at least partly, by enhancing defense system, adjusting energy and metabolic pathway and maintaining RNA structure.     

Genetic and physical finemapping of the Sc locus conferring indica-japonica hybrid sterility in rice （Oryza sativa L.）

Hybrid sterility is a major hindrance to utilizing the heterosis in indica-japonica hybrids. To isolate a gene Sc conferring the hybrid sterility, the locus was mapped using molecular markers and an F2 population derived from a cross between near isogenic lines. A primary linkage analysis showed that Sc was linked closely with 4 markers on chromosome 3, on which the genetic distance between a marker RG227 and Sc was 0.07 cM. Chromosome walking with a rice TAC genomic library was carried out using RG227 as a starting probe, and a contig of ca. 320 kb covering the Sc locus was constructed. Two TAC clones, M45EI4 and M90J01 that might cover the Sc locus, were partially sequenced. By searching the rice sequence databases with sequences of the TACs and RG227 a japonica rice BAC sequence, OSJNBb0078P24 was identified. By comparing the TAC and BAC sequences, six new PCR-based markers were developed. With these markers the Sc locus was further mapped to a region of 46 kb. The results suggest that the BAC OSJNBb0078P24 and TAC M45EI4 contain the Sc gene. Six ORFs were predicted in the focused 46-kb region.     

Genetic analysis and gene mapping of a dominant presenescing leaf gene <Emphasis Type="Italic">PSL3</Emphasis> in rice (<Emphasis Type="Italic">Oryza sativa</Emphasis> L.)

Leaf senescence as an active process is essential for plant survival and reproduction. However, premature senility is harmful to agricultural production. In this study, a rice mutant, named as psl3 (presescing leaf 3) isolated from EMS-treated Jinhui 10, displays obvious premature senility features both in morphological and physiological level. Genetic analysis showed that mutant trait was controlled by a single dominant gene (PSL3), which was located on rice chromosome 7 between SSR marker c7sr1 and InDel marker ID10 with an interval of 53.5 kb. The result may be useful for the isolation of the PSL3 gene.     

Expression of the intact C<Subscript>4</Subscript> type<Emphasis Type="Italic">pepc</Emphasis> gene cloned from maize in transgenic winter wheat

Maize intact C4-pepc gene was amplified through LA-PCR and successfully sub-cloned into modified vector pGreen0029 to form a stable expression construct named as pBAC214 (12 kb), which contains CaMV 35S promoter driven bar gene as selection marker. Comparing the cloned DNA sequences (6.7 kb) with published maize C4-pepc gene (GenBank accession E17154) sequences, the identity of DNA sequence alignment is 98.96%. There are only 49 differences between these two intact DNA sequences, of which 13 occur in the region of promoter, 18 in introns, and 18 in exons. The homology of mRNA sequence alignment is 99.38%, and the putative amino acids sequence identity is 99.38%. There are only 15 differences between these two mRNA, and these differences bring 4 sites mutant on the putative amino acids of PEPC protein. Through biolistic bombardment of PDS1000/He system, expression vector pBAC214 has been transformed into winter wheat. Southern blotting results show that the intact C4-pepc gene has been integrated into genome of winter wheat. SDS-PAGE analysis of leaf soluble protein in transgenic wheat showed that the intact C4opepc gene was well transcribed, spliced and translated as in maize. The enzyme activity of leaf PEPC in transgenic wheat has been detected. The activities of leaf PEPC increased over 3-5 times in some transgenic plants. The data of photosynthesis rate and transpiration rate of transgenic wheat flag leaves showed that the C4-pepc gene can increase the photosynthesis rate and transpiration rate of transgenic wheat.     

Comparative proteomics analysis of <Emphasis Type="Italic">OsNAS1</Emphasis> transgenic <Emphasis Type="Italic">Brassica napus</Emphasis> under salt stress

Salt stress is one of the major abiotic stresses in agricultural plants worldwide. We used proteomics to analyze the differential expression of proteins in transgenic OsNAS1 and non-transformant Brassica napus treated with 20 mmol/L Na₂CO₃. Total protein from the leaves was extracted and separated through a high-resolution and highly repetitive two-dimensional electrophoresis (2-DE) technology system. Twelve protein spots were reproducibly observed to be upregulated by more than 2-fold between transgenic and non-transformant B. napus. These 12 spots were digested in-gel with trypsin and characterized by matrix-assisted laser-desorption/ionization time-of-flight mass spectrometry (MALDI-TOF-MS) to obtain the peptide mass fingerprints. Protein database searching revealed that 5 of these proteins are involved in salt tolerance: dehydrogenase, glutathione S-transferase, peroxidase, 20S proteasome beta subunit, and ribulose-1,5-bisphosphate carboxylase/oxygenase. The potential functions of these identified proteins in substance and energy metabolism, stress tolerance, protein degradation, and cell defense are discussed. The salt tolerance of the transgenic rapeseed was significantly improved by the introduction of the OsNAS1 gene from Brazilian upland rice of Oryza sativa (cv. IAPAR 9).     

Ubi1 intron-mediated enhancement of the expression of Bt cry1Ah gene in transgenic maize （Zea mays L.）

The cry1Ah gene was one of novel insecticidal genes cloned from Bacillus thuringiensis isolate BT8. Two plant expression vectors containing cry1Ah gene were constructed. The first intron of maize ubiqutinl gene was inserted between the maize Ubiquitin promoter and cry1Ah gene in one of the plant expressing vectors （pUUOAH）. The two vectors were introduced into maize immature embryonic calli by microprojectile bombardment, and the reproductively plants were acquired. PCR and Southern blot analysis showed that foreign genes had been integrated into maize genome and inherited to the next generation stably. The ELISA assay to T1 and T2 generation plants showed that the expression of CrylAh protein in the construct containing the ubil intron （pUUOAH） was 20% higher than that of the intronless construct （pUOAH）. Bioassay results showed that the transgenic maize harboring cry1Ah gene had high resistance to the Asian corn borers and the insecticidal activity of the transgenic maize containing the ubil intron was higher than that of the intronless construct. These results indicated that the maize ubil intron can enhance the expression of the Bt cry1Ah gene in transgenic maize efficiently     

Fermentation of xylose to produce ethanol by recombinant <Emphasis Type="Italic">Saccharomyces cerevisiae</Emphasis> strain containing <Emphasis Type="Italic">XYLA</Emphasis> and <Emphasis Type="Italic">XKS1</Emphasis>

Fermentation of the pentose sugar xylose to produce ethanol using lignocellulosic biomass would make bioethanol production economically more competitive. Saccharomyce cerevisise, an efficient ethanol producer, cannot utilize xylose because it lacks the ability to convert xylose to its isomer xylulose. In this study, XYLA gene encoding xylose isomerase (XI) from Thermoanaerobacter tengcongensis MB4T and XKS1 gene encoding xylulokinase (XK) from Pichia stipitis were cloned and functionally coexpressed in Saccharomyces cerevisiae EF-326 to construct a recombinant xylose-utilizing strain. The resulting strain S. cerevisiae EF 1014 not only grew on xylose as sole carbon source, but also produced ethanol under anaerobic conditions. Fermentations performed with different xylose concentrations at different temperatures demonstrated that the highest ethanol productivity was 0.11 g/g xylose when xylose concentration was provided at 50 g/L. Under this condition, 28.4% of xylose was consumed and 1.54 g/L xylitol was formed. An increasing fermentation temperature from 30℃ to 37℃ did not improve ethanol yield.