Simultaneous detection of TNOS and P35S in transgenic soybean based on magnetic bicolor fluorescent probes.

A magnetic-separation-dual-targets fluorescent biosensor was fabricated to detect terminator nopaline synthase (TNOS) and promoter of cauliflower mosaic virus 35s (P35S) in transgenic soybean based on incorporation of bicolor CdTe quantum dots carried by silica nanospheres. In this protocol, the fixed probes for TNOS or P35S were magnetized firstly with Fe3O4@Au magnetic nanosphere by Au-S covalent bonding to achieve magnetized probes. Meanwhile, the capture probes for TNOS or P35S were functionalized with green or red fluorescent microspheres respectively to obtain fluorescently-labeled probes, which could emit relative strong green or red fluorescent signal. Two terminals of TNOS or P35S were recognized by magnetized probes and fluorescently-labeled probes respectively to form the sandwiched structures in the process of biosensor development subsequently, and it was separated by a magnet instantly. The fluorescence intensities of remnant supernatant were measured and analyzed accordingly to achieve simultaneous detection of TNOS and P35S. This biosensor exhibited a good dynamic range, low limit of detection and excellent selectivity in detecting transgenic soybean.

Complete genome sequence of a tentative new caulimovirus from the medicinal plant Atractylodes macrocephala.

A total of nine contigs related to caulimovirus-like sequences were detected using high-throughput paired-end RNA sequencing. An attempt to find the plant sample infected with this type of virus identified the medicinal plant Atractylodes macrocephala Koidzumi showing mild mottle symptoms. Subsequently, the complete DNA genome sequence of the Atractylodes virus was determined. The 8,105-nt genome of the virus was composed of six open reading frames and displayed the highest nucleotide sequence identity (70%) with soybean Putnam virus. Based upon the symptoms observed on the source plant, we propose to refer to this new member of the genus Caulimovirus as atractylodes mild mottle virus.

Mutations within A 35 amino acid region of P6 influence self-association, inclusion body formation, and Caulimovirus infectivity.

Cauliflower mosaic virus gene VI product (P6) is an essential protein that forms cytoplasmic, inclusion bodies (IBs). P6 contains four regions involved in self-association, termed D1-D4. D3 binds to D1, along with D4 and contains a spacer region (termed D3b) between two RNA-binding domains. Here we show D3b binds full-length P6 along with D1 and D4. Full-length P6s harboring single amino acid substitutions within D3b showed reduced binding to both D1 and D4. Full-length P6s containing D3b mutations and fused with green fluorescent protein formed inclusion-like bodies (IL-Bs) when expressed in Nicotiana benthamiana leaves. However, mutant P6s with reduced binding to D1 and D4, showed smaller IL-Bs, than wild type. Likewise, viruses containing these mutations showed a decrease in inoculated leaf viral DNA levels and reduced efficiency of systemic infection. These data suggest that mutations influencing P6 self-association alter IB formation and reduce virus infection.

Fabrication of DNA/graphene/polyaniline nanocomplex for label-free voltammetric detection of DNA hybridization.

A novel DNA electrochemical biosensor was described for the detection of specific gene sequences. Electrochemically reduced graphene oxide (ERGNO) was prepared on polyaniline (PAN) nanofibers modified glassy carbon electrode (GCE). Compared with the electrochemical reduction of graphene oxide directly on bare GCE (reduction potential: ca. -1.3V), more positive reduction potential (ca. -1V) for graphene oxide was observed with the PAN membrane existing. The formed ERGNO/PAN nanocomposites were applied to bind ssDNA probe via the non-covalent assembly. The surface density of ssDNA was calculated by voltammetric studies of redox cations ([Ru(NH(3))(6)](3+)), which were bound to the surface via electrostatic interaction with negative charged phosphate backbone of the DNA. After the hybridization of ssDNA probe with complementary DNA, the response of surface-bound [Ru(NH(3))(6)](3+) changed obviously, which could been adopted to recognize the DNA hybridization. Under optimal conditions, the dynamic range of the DNA biosensor for detecting the sequence-specific DNA of cauliflower mosaic virus (CaMV35S) gene was from 1.0×10(-13) to 1.0×10(-7)molL(-1), with a detection limit of 3.2×10(-14)molL(-1). This biosensor also showed a high degree of selectivity.

Identification of seed dormancy mutants by activation tagging.

Activation tagging is an important tool for gene discovery in plants. This method utilizes a T-DNA sequence that contains four tandem copies of the cauliflower mosaic virus 35S enhancer sequence or promoters oriented outward to the T-DNA border sequences. These elements enhance the expression of genes neighboring on either side of the randomly integrated T-DNA, resulting in gain-of-function phenotypes. Activation tagging has identified a number of genes, including those fundamental to plant development, such as the floral inducer gene, FLOWERING LOCUS T (FT ). The methods surrounding activation-tagging approaches are described in this chapter. While seeds have generally not been the targets of these methods in the past, activation tagging provides a powerful approach to uncover genes involved in seed dormancy and germination, including those that mediate hormone signal transduction.

Genomic characterization of pararetroviral sequences in wild Dahlia spp. in natural habitats.

The genome structure and organization of endogenous caulimovirus sequences from dahlia (Dahlia spp), dahlia mosaic virus (DMV)-D10 from three wild species, D. coccinea (D10-DC), D. sherffii (D10-DS) and D. tenuicaulis (D10-DT), were determined and compared to those from cultivated species of dahlia, D. variabilis (DvEPRS). The complete ca. 7-kb dsDNA genomes of D10-DC, D10-DS, and D10-DT had a structure and organization typical of a caulimovirus and shared 89.3 to 96.6% amino acid sequence identity in various open reading frames (ORF) when compared to DvEPRS. The absence of the aphid transmission factor and the truncated coat protein fused with the reverse transcriptase ORF were common among these DMV-D10 isolates from wild Dahlia species.

Structural insights into the molecular mechanisms of cauliflower mosaic virus transmission by its insect vector.

Cauliflower mosaic virus (CaMV) is transmitted from plant to plant through a seemingly simple interaction with insect vectors. This process involves an aphid receptor and two viral proteins, P2 and P3. P2 binds to both the aphid receptor and P3, itself tightly associated with the virus particle, with the ensemble forming a transmissible viral complex. Here, we describe the conformations of both unliganded CaMV P3 protein and its virion-associated form. X-ray crystallography revealed that the N-terminal domain of unliganded P3 is a tetrameric parallel coiled coil with a unique organization showing two successive four-stranded subdomains with opposite supercoiling handedness stabilized by a ring of interchain disulfide bridges. A structural model of virus-liganded P3 proteins, folding as an antiparallel coiled-coil network coating the virus surface, was derived from molecular modeling. Our results highlight the structural and biological versatility of this coiled-coil structure and provide new insights into the molecular mechanisms involved in CaMV acquisition and transmission by the insect vector.

Cauliflower mosaic virus gene VI product N-terminus contains regions involved in resistance-breakage, self-association and interactions with movement protein.

Cauliflower mosaic virus (CaMV) gene VI encodes a multifunctional protein (P6) involved in the translation of viral RNA, the formation of inclusion bodies, and the determination of host range. Arabidopsis thaliana ecotype Tsu-0 prevents the systemic spread of most CaMV isolates, including CM1841. However, CaMV isolate W260 overcomes this resistance. In this paper, the N-terminal 110 amino acids of P6 (termed D1) were identified as the resistance-breaking region. D1 also bound full-length P6. Furthermore, binding of W260 D1 to P6 induced higher beta-galactosidase activity and better leucine-independent growth in the yeast two-hybrid system than its CM1841 counterpart. Thus, W260 may evade Tsu-0 resistance by mediating P6 self-association in a manner different from that of CM1841. Because Tsu-0 resistance prevents virus movement, interaction of P6 with P1 (CaMV movement protein) was investigated. Both yeast two-hybrid analyses and maltose-binding protein pull-down experiments show that P6 interacts with P1. Although neither half of P1 interacts with P6, the N-terminus of P6 binds P1. Interestingly, D1 by itself does not interact with P1, indicating that different portions of the P6 N-terminus are involved in different activities. The P1-P6 interactions suggest a role for P6 in virus transport, possibly by regulating P1 tubule formation or the assembly of movement complexes.

Cauliflower mosaic virus protein P6 is a suppressor of RNA silencing.

We infected a transgenic Arabidopsis line (GxA), containing an amplicon-silenced 35S : : GFP transgene, with cauliflower mosaic virus (CaMV), a plant pararetrovirus with a DNA genome. Systemically infected leaves showed strong GFP fluorescence and amplicon transcripts were detectable in Northern blots, indicating that silencing of GFP had been suppressed during CaMV-infection. Transgenic Arabidopsis lines expressing CaMV protein P6, the major genetic determinant of symptom severity, were crossed with GxA. Progeny showed strong GFP fluorescence throughout and amplicon transcripts were detectable in Northern blots, indicating that P6 was suppressing local and systemic silencing. However, levels of 21 nt siRNAs derived from the GFP transgene were not reduced. In CaMV-infected plants, the P6 transgene did not reduce levels of CaMV leader-derived 21 and 24 nt siRNAs relative to levels of CaMV 35S RNA. These results demonstrate that CaMV can efficiently suppress silencing of a GFP transgene, and that P6 acts as a silencing suppressor.

Structure of the mature P3-virus particle complex of cauliflower mosaic virus revealed by cryo-electron microscopy.

The cauliflower mosaic virus (CaMV) has an icosahedral capsid composed of the viral protein P4. The viral product P3 is a multifunctional protein closely associated with the virus particle within host cells. The best-characterized function of P3 is its implication in CaMV plant-to-plant transmission by aphid vectors, involving a P3-virion complex. In this transmission process, the viral protein P2 attaches to virion-bound P3, and creates a molecular bridge between the virus and a putative receptor in the aphid's stylets. Recently, the virion-bound P3 has been suggested to participate in cell-to-cell or long-distance movement of CaMV within the host plant. Thus, as new data accumulate, the importance of the P3-virion complex during the virus life-cycle is becoming more and more evident. To provide a first insight into the knowledge of the transmission process of the virus, we determined the 3D structures of native and P3-decorated virions by cryo-electron microscopy and computer image processing. By difference mapping and biochemical analysis, we show that P3 forms a network around the capsomers and we propose a structural model for the binding of P3 to CaMV capsid in which its C terminus is anchored deeply in the inner shell of the virion, while the N-terminal extremity is facing out of the CaMV capsid, forming dimers by coiled-coil interactions. Our results combined with existing data reinforce the hypothesis that this coiled-coil N-terminal region of P3 could coordinate several functions during the virus life-cycle, such as cell-to-cell movement and aphid-transmission.

P6 protein of Cauliflower mosaic virus, a translation reinitiator, interacts with ribosomal protein L13 from Arabidopsis thaliana.

The P6 protein of Cauliflower mosaic virus (CaMV) transactivates translation of the CaMV 35S polycistronic pregenomic RNA and its spliced versions, and thus allows synthesis of a complete set of viral proteins. Previous studies have shown that P6 interacts with plant L18 and L24 ribosomal proteins and initiation factor eIF3, and it has been proposed that these interactions are involved in the reinitiation of translation of polycistronic viral RNAs. This study characterizes a novel cellular partner of P6, the ribosomal protein L13 from Arabidopsis thaliana. Far-Western assays performed with several P6 deletion mutants have shown that L13 interacts with the miniTAV of P6, which represents the minimal domain for transactivation, suggesting that the P6-L13 interaction might also be involved in this process. L13 and L18 were found to bind to the same region within the miniTAV. Competition assays between L18 and L13 for binding to miniTAV suggest that interactions between P6 and these ribosomal proteins involve separate P6 molecules, and/or occur at different stages of translation or in the context of another function also mediated by P6.

Stable expression of foreign proteins in herbaceous and apple plants using Apple latent spherical virus RNA2 vectors.

Infectious cDNA clones of Apple latent spherical virus (ALSV)-RNA1 (pEALSR1) and -RNA2 (pEALSR2) were constructed using an enhanced 35S promoter. A viral vector was constructed from pEALSR2 by creating artificial protease processing sites by duplicating the Q/G protease cleavage site between 42KP and Vp25. Eight RNA2-derived vectors expressing GFP with varied sizes of duplications around the 42KP/Vp25 junction were constructed and tested for infectivity in Chenopodium quinoa. The results indicated that greater than five aa from the C-terminus of 42KP and N-terminus of Vp25 in duplication are necessary for systemic infection. In infected C. quinoa plants, GFP fluorescence was observed in both inoculated and upper leaves. Serial passages of the viruses derived from the above vectors in C. quinoa showed that the size of duplications affected the stability of the GFP gene. The version of the RNA2-vector (pER2L5R5GFP) with the shortest duplications and its silent mutant version could stably express GFP in leaves even after at least nine serial passages. ALSV-RNA2 vector has a capacity to maintain a DNA insert as long as 1300 bp because Apple chlorotic leaf spot virus movement protein (50KP) gene could be expressed in C. quinoa. Inoculation of a virus derived from pER2L5R5GFP to apple seedlings resulted in the expression of GFP fluorescence in uninoculated upper leaves, indicating that the vector is available for the expression of foreign genes in apple trees.

Biochemical characterization of the helper component of Cauliflower mosaic virus.

The helper component of Cauliflower mosaic virus is encoded by viral gene II. This protein (P2) is dispensable for virus replication but required for aphid transmission. The purification of P2 has never been reported, and hence its biochemical properties are largely unknown. We produced the P2 protein via a recombinant baculovirus with a His tag fused at the N terminus. The fusion protein was purified by affinity chromatography in a soluble and biologically active form. Matrix-assisted laser desorption time-of-flight mass spectrometry demonstrated that P2 is not posttranslationally modified. UV circular dichroism revealed the secondary structure of P2 to be 23% alpha-helical. Most alpha-helices are suggested to be located in the C-terminal domain. Using size exclusion chromatography and aphid transmission testing, we established that the active form of P2 assembles as a huge soluble oligomer containing 200 to 300 subunits. We further showed that P2 can also polymerize as long paracrystalline filaments. We mapped P2 domains involved in P2 self-interaction, presumably through coiled-coil structures, one of which is proposed to form a parallel trimer. These regions have previously been reported to also interact with viral P3, another protein involved in aphid transmission. Possible interference between the two types of interaction is discussed with regard to the biological activity of P2.

Tetramerization is a conserved feature of the virion-associated protein in plant pararetroviruses.

All plant pararetroviruses belong to the Caulimoviridae family. This family contains six genera of viruses with different biological, serological, and molecular characteristics. Although some important mechanisms of viral replication and host infection are understood, much remains to be discovered about the many functions of the viral proteins. The focus of this study, the virion-associated protein (VAP), is conserved among all members of the group and contains a coiled-coil structure that has been shown to assemble as a tetramer in the case of cauliflower mosaic virus. We have used the yeast two-hybrid system to characterize self-association of the VAPs of four distinct plant pararetroviruses, each belonging to a different genus of Caulimoviridae. Chemical cross-linking confirmed that VAPs assemble into tetramers. Tetramerization is thus a common property of these proteins in plant pararetroviruses. The possible implications of this conserved feature for VAP function are discussed.

Stabilization of cauliflower mosaic virus P3 tetramer by covalent linkage.

Cauliflower mosaic virus (CaMV) open reading frame (ORF) III encodes a 15 kDa protein (P3) that is indispensable for viral infectivity. Although P3 has been shown to be a prerequisite for CaMV aphid transmission, its role in viral replication remains unknown. We previously showed that P3 forms a tetramer in planta and that P3 tetramer co-sediments with viral coat protein on sucrose gradient centrifugation, suggesting that a tetramer may be the functional form of P3. We presumed that disulfide bonds were involved in tetramer formation because 1) the tetramer was detected by Western blotting after electrophoresis under non-reducing conditions, and 2) the cysteine-X-cysteine motif is well conserved in CaMV P3 and P3 homologues among Caulimoviruses. Therefore we mutated either or both of the cysteine residues of CaMV P3. The mutant viruses were infectious and accumulated to a similar extent as the wild-type. An analysis of mutant proteins confirmed that the wild-type P3 molecules in the tetramer are covalently bound with one another through disulfide bonds. It was also suggested that mutant proteins are less stable than wild-type protein in planta. Furthermore, sedimentation study suggested that the disulfide bonds are involved in stable association of P3 with CaMV virions or virion-like particles, or both. The mutant viruses could be transmitted by aphids. These results suggested that the covalent bonds in P3 tetramer are dispensable for biological activity of P3 under experimental situations and may have some biological significance in natural infection in the field.

Cauliflower mosaic virus ORF III product forms a tetramer in planta: its implication in viral DNA folding during encapsidation.

Cauliflower mosaic virus (CaMV) open reading frame (ORF) III encodes a 15 kDa protein; the function of which is as yet unknown. This protein has non-sequence-specific DNA binding activity and is associated with viral particles, suggesting that the ORF III product (P3) is involved in the folding of CaMV DNA during encapsidation. In this study, we demonstrated that P3 forms a tetramer in CaMV-infected plants. A P3-related protein with an apparent molecular weight of 60 kDa was detected by Western blotting analysis using anti-P3 antiserum under non-reducing conditions, while only 15 kDa P3 was detected under reducing conditions. Analysis of P3 using viable mutants with a 27-bp insertion in either ORF III or IV revealed that the 60 kDa protein was a tetramer of P3. The P3 tetramer co-sedimented with viral coat protein in multiple fractions on sucrose gradient centrifugation, suggesting that P3 tetramer binds to mature and immature virions. These results strongly suggested that CaMV P3 forms a tetramer in planta and that disulfide bonds are involved in its formation and/or stabilization. The finding of P3 tetramer in planta suggested that viral DNA would be folded compactly by the interaction with multiple P3 molecules, which would form tetramers, while being packaged into the capsid shell.

The open reading frame III product of cauliflower mosaic virus forms a tetramer through a N-terminal coiled-coil.

The open reading frame III product of cauliflower mosaic virus is a protein of 15 kDa (p15) that is essential for the virus life cycle. It was shown that the 34 N-terminal amino acids are sufficient to support protein-protein interaction with the full-length p15 in the yeast two-hybrid system. A corresponding peptide was synthesized and a recombinant p15 was expressed in Escherichia coli and purified. Circular dichroism spectroscopy showed that the peptide and the full-length protein can assume an alpha-helical conformation. Analytical centrifugation allowed to determine that p15 assembles as a rod-shaped tetramer. Oxidative cross-linking of N-terminal cysteines of the peptide generated specific covalent oligomers, indicating that the N terminus of p15 is a coiled-coil that assembles as a parallel tetramer. Mutation of Lys22 into Asp destabilized the tetramer and put forward the presence of a salt bridge between Lys22 and Asp24 in a model building of the stalk. These results suggest a model in which the stalk segment of p15 is located at its N terminus, followed by a hinge that provides the space for presenting the C terminus for interactions with nucleic acids and/or proteins.

Petunia vein-clearing virus: a plant pararetrovirus with the core sequences for an integrase function.

Petunia vein-clearing virus (PVCV) is a plant pararetrovirus that has some features of retrotransposons. It encapsidates dsDNA and has isometric particles and inclusion bodies similar to those of caulimoviruses. The PVCV genome of 7205 bp has two large ORFs in the transcribed strand and a methionine tRNA primer-binding site in its 663-bp intergenic region. The N-terminal position of the large protein (126 kDa) encoded by ORF I has similarity to the movement protein of caulimoviruses. Toward the C-terminus of this same polyprotein are the two distinctive sequence elements [HHCC and DD(35)E] of the integrase function of retroviruses and retrotransposons. ORF II of PVCV encodes a protein of 125 kDa with domains for an RNA-binding element, common to the gag gene of retroelements, followed by consensus sequences for an acid protease, reverse transcriptase, and ribonuclease H. Hence, the gag equivalent (capsid protein) and pol gene of PVCV are part of the same polyprotein. Phylogenetic comparison of the reverse transcriptase of PVCV with that of various other retroelements grouped PVCV between caulimoviruses and the Ty3/gypsy retrotransposons, suggesting that PVCV is a divergent member of the caulimoviruses.

Solid-phase synthesis, metal binding and folding properties of caulimovirus-related 'zinc finger'.

A 17-residue peptide containing the caulimovirus-related "zinc finger' was prepared by solid-phase peptide synthesis. Fluorescence measurements showed that the tryptophan quantum yield was Zn(2+)-dependent, allowing a 1:1 a stoichiometry for the complex to be determined. The structure of the peptide was characterized using circular dichroic spectroscopy, which indicates that the peptide exhibits a random coiled conformation in the absence of zinc but appears to form an ordered structure in the presence of zinc.

Repeated sequences from the Arabidopsis thaliana genome function as enhancers in transgenic tobacco.

Sixteen segments of Arabidopsis thaliana DNA that function as enhancers in transgenic tobacco plants were isolated using the pROA97 enhancer cloning vehicle and library transformation of Nicotiana tabacum. The sequences were compared for AT content, homology, repeated motifs, and expression pattern in transgenic N. tabacum. The sequences were average with respect to the AT content of A. thaliana DNA. They could be placed into seven homology groups. Five of the sequences are single-copy sequences. The remaining eleven sequences represent two homology groups. Homology Group I contains seven sequences with minor differences. Homology Group II contains four sequences with minor differences. Two repeated motifs were identified (5'-CCTCT-3' and 5'-AAGGAT-3'). Both repeated motifs are found in other plant enhancers, and in the promoter region of the cauliflower mosaic virus 35S gene. In the 35S gene TATA region, the motifs can form two alternative stem-loop structures. The TATATAA sequence is located in the loop region of both stem-loop structures.