Reassessment of Viroid RNA Cytosine Methylation Status at the Single Nucleotide Level.

Composed of a few hundreds of nucleotides, viroids are infectious, circular, non-protein coding RNAs able to usurp plant cellular enzymes and molecular machineries to replicate and move in their hosts. Several secondary and tertiary RNA structural motifs have been implicated in the viroid infectious cycle, but whether modified nucleotides, such as 5C-methylcytosine (m5C), also play a role has not been deeply investigated so far. Here, the possible existence of m5C in both RNA polarity strands of potato spindle tuber viroid and avocado sunblotch viroid -which are representative members of the nucleus- and chloroplast-replicating viroids, respectively- has been assessed at single nucleotide level. We show that a standard bisulfite protocol efficiently used for identifying m5C in cellular RNAs may generate false positive results in the case of the highly structured viroid RNAs. Applying a bisulfite conversion protocol specifically adapted to RNAs with high secondary structure, no m5C was identified in both polarity strands of both viroids, indicating that this specific nucleotide modification does not likely play a role in viroid biology.

A nuclear-replicating viroid antagonizes infectivity and accumulation of a geminivirus by upregulating methylation-related genes and inducing hypermethylation of viral DNA.

DNA methylation and post-transcriptional gene silencing play critical roles in controlling infection of single-stranded (ss) DNA geminiviruses and ssRNA viroids, respectively, but both pathogens can counteract these host defense mechanisms and promote their infectivity. Moreover, a specific role of DNA methylation in viroid-host interactions is not yet confirmed. Here, using an experimental system where two nuclear-replicating agents, the geminivirus tomato yellow leaf curl Sardinia virus (TYLCSV) and potato spindle tuber viroid (PSTVd), co-infect their common host tomato, we observed that PSTVd severely interferes with TYLCSV infectivity and accumulation, most likely as a consequence of strong activation of host DNA methylation pathways. In fact, PSTVd alone or in co-infection with TYLCSV significantly upregulates the expression of key genes governing DNA methylation in plants. Using methylation-sensitive restriction and bisulfite conversion assays, we further showed that PSTVd infection promotes a strong hypermethylation of TYLCSV DNA, thus supporting a mechanistic link with the antagonism of the viroid on the virus in co-infected tomato plants. These results describe the interaction between two nuclear-replicating pathogens and show that they differentially interfere with DNA methylation pathways.

A single polyprobe for detecting simultaneously eight pospiviroids infecting ornamentals and vegetables.

The spread of viroids belonging to the genus Pospiviroid (family Pospiviroidae), recorded recently in ornamentals and vegetables in several European countries, calls for fast, efficient and sensitive detection methods. Based on bioinformatics analyses of sequence identity among all pospiviroids, a digoxigenin-labeled polyprobe (POSPIprobe) was developed that, when tested by dot-blot and Northern-blot hybridization, detected Potato spindle tuber viroid, Citrus exocortis viroid, Columnea latent viroid, Mexican papita viroid, Tomato planta macho viroid, Tomato apical stunt viroid, Pepper chat fruit viroid and Chrysanthemum stunt viroid. The end-point detection limits of the POSPIprobe ranged from 5(-2) to 5(-4), and from 5(-1) to 5(-3) for nucleic acid preparations obtained by phenol extraction and silica-capture, respectively, similar to those of single probes. Based on sequence identity, the POSPIprobe is expected to detect also the two pospiviroid species not tested in this study (Tomato chlorotic dwarf viroid and Iresine viroid-1). Dot-blot assays with the POSPIprobe were validated by testing 68 samples from tomato, chrysanthemum and argyranthemum infected by different pospiviroids as revealed by RT-PCR, thus confirming the potential of this polyprobe for quarantine, certification and survey programs.

Development and validation of a multiplex RT-PCR method for the simultaneous detection of five grapevine viroids.

Grapevine yellow speckle viroid 1 (GYSVd-1), Grapevine yellow speckle viroid 2 (GYSVd-2), Australian grapevine viroid (AGVd), Hop stunt viroid (HSVd) and Citrus exocortis viroid (CEVd) are the five viroids known to infect naturally grapevines. We developed a multiplex RT-PCR (mRT-PCR) method for the simultaneous detection of these five viroids and the amplification of the cDNA fragment of a host-derived mRNA (actin mRNA) as an internal positive control. Specific primers for each targeted viroid were designed by taking into account the sequence variability within and between the viroid species and tested in silico. The method was validated by testing 57 grapevine samples from Iran and showed reliability and high sensitivity. The RT-PCR-negative samples were further assayed by Northern-blot hybridization. For this, a method was developed for the simultaneous detection of three different grapevine viroids on a single hybridization membrane. In this survey, HSVd, GYSVd-1, AGVd, and GYSVd-2 were detected in 100, 95, 93, and 65% of the samples tested, respectively, confirming the wide distribution of these viroids in Iran. CEVd was not detected in any of the samples collected. Based on these results, HSVd is proposed as a positive internal control for mRT-PCR in the areas where this viroid is widespread, so as to reduce the time and costs of DNase treatment, which is required when a host-derived internal control is used. The mRT-PCR method has the potential to be used routinely for large-scale surveys and certification programs.

Mitochondrial localization of human FAD synthetase isoform 1.

FAD synthetase or ATP:FMN adenylyl transferase (FADS or FMNAT, EC 2.7.7.2) is a key enzyme in the metabolic pathway that converts riboflavin into the redox cofactor FAD. We face here the still controversial sub-cellular localization of FADS in eukaryotes. First, by western blotting experiments, we confirm the existence in rat liver of different FADS isoforms which are distinct for molecular mass and sub-cellular localization. A cross-reactive band with an apparent molecular mass of 60 kDa on SDS-PAGE is localized in the internal compartments of freshly isolated purified rat liver mitochondria. Recently we have identified two isoforms of FADS in humans, that differ for an extra-sequence of 97 amino acids at the N-terminus, present only in isoform 1 (hFADS1). The first 17 residues of hFADS1 represent a cleavable mitochondrial targeting sequence (by Target-P prediction). The recombinant hFADS1 produced in Escherichia coli showed apparent K(m) and V(max) values for FMN equal to 1.3+/-0.7 microM and 4.4+/-1.3 nmol x min(-1) x mg protein(-1), respectively, and was inhibited by FMN at concentration higher than 1.5 microM. The in vitro synthesized hFADS1, but not hFADS2, is imported into rat liver mitochondria and processed into a lower molecular mass protein product. Immunofluorescence confocal microscopy performed on BHK-21 and Caco-2 cell lines transiently expressing the two human isoforms, definitively confirmed that hFADS1, but not hFADS2, localizes in mitochondria.

Over-expression in Escherichia coli, purification and characterization of isoform 2 of human FAD synthetase.

FAD synthetase (FADS) (EC 2.7.7.2) is a key enzyme in the metabolic pathway that converts riboflavin into the redox cofactor FAD. The human isoform 2 of FADS (hFADS2), which is the product of FLAD1 gene, was over-expressed in Escherichia coli as a T7-tagged protein and identified by MALDI-TOF MS analysis. Its molecular mass, calculated by SDS-PAGE, was approx. 55 kDa. The expressed protein accounted for more than 40% of the total protein extracted from the cell culture; 10% of it was recovered in a soluble and nearly pure form by Triton X-100 treatment of the insoluble cell fraction. hFADS2 possesses FADS activity and has a strict requirement for MgCl2, as demonstrated in a spectrophotometric assay. The purified recombinant isoform 2 showed a kcat of 3.6 x 10(-3)s(-1) and exhibited a KM value for FMN of about 0.4 microM. The expression of the hFADS2 isoform opens new perspectives in the structural studies of this enzyme and in the design of antibiotics based on the functional differences between the bacterial and the human enzymes.

Over-expression in Escherichia coli and characterization of two recombinant isoforms of human FAD synthetase.

FAD synthetase (FADS) (EC 2.7.7.2) is a key enzyme in the metabolic pathway that converts riboflavin into the redox cofactor FAD. Two hypothetical human FADSs, which are the products of FLAD1 gene, were over-expressed in Escherichia coli and identified by ESI-MS/MS. Isoform 1 was over-expressed as a T7-tagged protein which had a molecular mass of 63kDa on SDS-PAGE. Isoform 2 was over-expressed as a 6-His-tagged fusion protein, carrying an extra 84 amino acids at the N-terminal with an apparent molecular mass of 60kDa on SDS-PAGE. It was purified near to homogeneity from the soluble cell fraction by one-step affinity chromatography. Both isoforms possessed FADS activity and had a strict requirement for MgCl(2), as demonstrated using both spectrophotometric and chromatographic methods. The purified recombinant isoform 2 showed a specific activity of 6.8+/-1.3nmol of FAD synthesized/min/mg protein and exhibited a K(M) value for FMN of 1.5+/-0.3microM. This is the first report on characterization of human FADS, and the first cloning and over-expression of FADS from an organism higher than yeast.