Integrating multiple criteria for the characterization of Psammotettix populations in European cereal fields.

The wheat dwarf disease is among the most damaging diseases in cereals. Its aetiological agent is the Wheat dwarf virus (WDV), which is exclusively transmitted from plant to plant by leafhoppers from the genus Psammotettix (Hemiptera, Cicadellidae). The parameters linked to the WDV/Psammotettix pathosystem are still poorly understood. We studied Psammotettix individuals collected in wheat and barley fields in France and, as a comparison, from grassland at agroecological interface in West Slovenia. Species identity of males and females has been determined using multiple criteria. In the first step, the characterization of the collected individuals included recordings of vibrational signals used in mating behaviour and morphometric analyses. In addition, a 442 nt sequence of the mitochondrial cytochrome oxydase I (COI) gene was obtained for some individuals and compared to COI sequences of the Psammotettix leafhoppers available in public databases. In the cereal fields in France, P sammotettix alienus was the most numerous species; however, it sometimes occurred together with Psammotettix confinis, while in the grasslands in Slovenia, the third syntopic species in Psammotettix community was Psammotettix helvolus. The temporal parameters of the P. alienus male calling song that were measured in this study were very similar to those measured in a previous study. The local biotic and/or abiotic parameters most likely influence the life history of Psammotettix leafhoppers, and the proportion of viruliferous individuals collected in cereal fields was 14.9%, while leafhoppers collected in Slovenia were virus-free. Taken together, results show that more detailed information on population structure of Psammotettix leafhoppers is crucial for providing an insight into the epidemiology of wheat dwarf disease.

Evolutionary Pathways to Break Down the Resistance of Allelic Versions of the PVY Resistance Gene va.

Emergence of viral genotypes can make control strategies based on resistance genes ineffective. A few years after the deployment of tobacco genotypes carrying alleles of the Potato virus Y (PVY) recessive resistance gene va, virulent PVY isolates have been reported, suggesting the low durability of va. To have a broader view of the evolutionary processes involved in PVY adaptation to va, we studied mutational pathways leading to the emergence of PVY resistance-breaking populations. The viral genome-linked protein (VPg) has been described to be potentially involved in va adaptation. Analyses of the VPg sequence of PVY isolates sampled from susceptible and resistant tobacco allowed us to identify mutations in the central part of the VPg. Analysis of the virulence of wild-type isolates with known VPg sequences and of mutated versions of PVY infectious clones allowed us to (i) validate VPg as the PVY virulence factor corresponding to va, (ii) highlight the fact that virulence gain in PVY occurs rapidly and preferentially by substitution at position AA105 in the VPg, and (iii) show that the 101G substitution in the VPg of a PVYC isolate is responsible for cross-virulence toward two resistance sources. Moreover, it appears that the evolutionary pathway of PVY adaptation to va depends on both virus and host genetic backgrounds.

Specific detection and quantification of virulent/avirulent Phytophthora infestans isolates using a real-time PCR assay that targets polymorphisms of the Avr3a gene.

Molecular tools that allow intraspecific quantification and discrimination of pathogen isolates are useful to assess fitness of competitors during mixed infections. However, methods that were developed for quantifying Phytophthora infestans are only specific at the species level. Here, we reported a TaqMan-based real-time PCR assay allowing, according to the specificity of the used probes, an accurate quantification of different proportions of two genetically distinct clones of P. infestans in mixed fractions. Indeed, in addition to a primer specific to P. infestans, two primers and two TaqMan(®) probes that target single-nucleotide polymorphisms located in the Avr3a/avr3a virulence gene sequence were designed. The reliability of the method was tested on serially diluted fractions containing plasmid DNA with either the Avr3a or the avr3a sequences at concentrations ranging from 10(2) to 10(8)  copies per µl. Based on its specificity, sensitivity and repeatability, the proposed assay allowed a quantification of the targeted DNA sequence in fractions with a Avr3a/avr3a ratio in the range 1/99 to 99/1. The reliability of the test was also checked for counting zoospores. Applications for future research in P. infestans/host quantitative interactions were also discussed.

Evaluation of the hemostatic potential including thrombin generation of three different therapeutic pathogen-reduced plasmas.

BACKGROUND AND OBJECTIVES: Several pathogen inactivation methods currently applied to therapeutic plasma may result in products with different hemostatic properties. This study aims at evaluating and comparing the hemostatic potential of different therapeutic plasma preparations currently available in France. MATERIALS AND METHODS: We studied three types of pathogen-reduced plasma for transfusion (MB/light, Amotosalen/UVA, industrial S/D plasma). Quarantine, non-pathogen-reduced plasma, was used as a control. This study compared more specifically the content in FVIII, fibrinogen (clottable and antigen assays) and ADAMTS-13 and evaluated the intrinsic hemostatic properties using a thrombin generation test [Calibrated Automated Thrombogram (CAT)] at high and low concentrations of tissue factor to assess the maximum quantity of thrombin generated or the contribution of FVIII and FIX in the amplification phase of thrombin generation, respectively. RESULTS: The median FVIII concentration was >70 IU/dl for each preparation. Endogenous thrombin potential values were significantly different among the methods of plasma preparation (P<0·001) but were all in the range of the values measured in donors' plasma. Control by the thrombomodulin-activated protein C system was preserved in all preparations (>50% inhibition of endogenous thrombin potential). Fibrinogen concentrations were all within normal range but fibrinogen levels were lower in the plasmas treated with photochemical methods. ADAMTS-13 levels were preserved. CONCLUSION: The hemostatic potential appears well preserved in all therapeutic plasmas tested but there are some differences between preparations, the clinical relevance of which remains to be elucidated.

[Potato virus Y (PVY): from its discovery to the latest outbreaks]. / Le virus Y de la pomme de terre (PVY) : de la première description aux derniers épisodes d'émergence.

Potato virus Y (PVY, family Potyviridae, genus Potyvirus) is one of the most economically important viruses infecting potato. This plant virus is transmitted by aphids and is present in all potato growing areas across the world. Thanks to the steady set-up of biological, serological and molecular detection/characterization tools, PVY potato strain isolates have been classified in groups (PVYN, PVYO, PVYC, PVYZ and PVYE) or as sub-groups (PVYNTN and PVYN-W). Epidemiological data available for PVY show the recent modification of PVY group and sub-group proportions in PVY populations. This modification has led to the current prevalence of necrotic recombinant PVY isolates. In order to identify factors involved in this evolution of PVY populations, characterization of i) the molecular determinants of necrotic properties, ii) the impact of the increase of PVY virulence and aggressiveness on fitness, iii) the role of recombination in PVY evolution and iv) the genetic variability of viral populations have been carried out. The main results of this research have been combined with data already published to write the present review.

Two-dimensional electrophoresis of proteins discriminates aphid clones of Sitobion avenae differing in BYDV-PAV transmission.

Aset of 39 F1 Sitobion avenae clones was obtained by selfing a poorly efficient BYDV-PAV vector clone. These clones were genetically typed by 11 microsatellite loci, and tested for BYDV-PAV4 transmission to barley. The 39 clones displayed a continuum in transmission percentages, from 0% to 88% with a significant clone effect. From this set, two highly efficient (HEV) and two poorly efficient (PEV) vectoring clones were more precisely characterized for transmission of two other PAV isolates. The molecular bases of the lower transmissibility of BYDV-PAV4 by PEV clones and of the aphid vectoring properties were investigated respectively by comparing the sequences corresponding to structural proteins (CP and RTD) of BYDV, and by using proteomic analysis of aphids in two dimensional electrophoresis (2-DE) with immobilized pH gradients (IPG) after an improved protein extraction. Four residues specific to BYDV-PAV4 located in the CP sequence (A(24) and L(130)) or in the RTD region (M(334) and S(456)) could be responsible for the lower transmissibility of this isolate by PEV clones. Among a total of 2150 well-resoluted spots scored on S. avenae proteinic pattern, only twelve proteins were qualitatively or quantitatively different between clones. Four out of them discriminated HEV and PEV groups.

Early detection of cacao swollen shoot virus using the polymerase chain reaction.

A polymerase chain reaction assay was developed which allows early detection of cacao swollen shoot virus (CSSV) in DNA extracts from cacao plantlets agroinoculated with the Togolese isolate Agou 1. The primers used were derived from badnavirus conserved sequences and nucleic acid was extracted with the Plant DNeasy extraction kit (Qiagen). CSSV genome was detectable between 6 and 20 days after inoculation. The first leaf symptoms appeared after 4 weeks and the first shoot swelling symptoms after 8 weeks.

Interaction between the open reading frame III product and the coat protein is required for transmission of cauliflower mosaic virus by aphids.

Transmission of cauliflower mosaic virus (CaMV) by aphids requires two viral nonstructural proteins, the open reading frame (ORF) II and ORF III products (P2 and P3). An interaction between a C-terminal domain of P2 and an N-terminal domain of P3 is essential for transmission. Purified particles of CaMV are efficiently transmitted only if aphids, previously fed a P2-containing solution, are allowed to acquire a preincubated mixture of P3 and virions in a second feed, thus suggesting a direct interaction between P3 and coat protein. Herein we demonstrate that P3 directly interacts with purified viral particles and unassembled coat protein without the need for any other factor and that P3 mediates the association of P2 with purified virus particles. The interaction domain of P3 is located in its C-terminal half, downstream of the P3-P2 interaction domain but overlapping a region which binds nucleic acids. Mutagenesis of P3 which interferes with the interaction between P3 and virions is correlated with the loss of transmission by aphids. Taken together, our results demonstrate that P3 plays a crucial role in the formation of the CaMV transmissible complex by serving as a bridge between P2 and virus particles.

Aphid transmission of cauliflower mosaic virus requires the viral PIII protein.

The open reading frame (ORF) III product (PIII) of cauliflower mosaic virus is necessary for the infection cycle but its role is poorly understood. We have used in vitro protein binding ('far Western') assays to demonstrate that PIII interacts with the cauliflower mosaic virus (CaMV) ORF II product (PII), a known aphid transmission factor. Aphid transmission of purified virions of the PII-defective strain CM4-184 was dependent upon added PII, but complementation was efficient only in the presence of PIII, demonstrating the requirement of PIII for transmission. Deletion mutagenesis mapped the interaction domains of PIII and PII to the 30 N-terminal and 61 C-terminal residues of PIII and PII, respectively. A model for interaction between PIII and PII is proposed on the basis of secondary structure predictions. Finally, a direct correlation between the ability of PIII and PII to interact and aphid transmissibility of the virus was demonstrated by using mutagenized PIII proteins. Taken together, these data argue strongly that PIII is a second 'helper' factor required for CaMV transmission by aphids.

In situ localization of cacao swollen shoot virus in agroinfected Theobroma cacao.

Cacao swollen shoot virus (CSSV) is a small non-enveloped bacilliform virus with a double-stranded DNA genome. A very restricted host range and difficulties in transmitting the virus, either mechanically or via its natural vector, have hindered the study of cacao swollen shoot disease. As an alternative to the particle-bombardment method previously reported, we investigated another approach to infect Theobroma cacao. A greater-than-unit length copy (1.2) of the CSSV DNA genome was cloned into the Agrobacterium binary vector pBin 19 and was transferred into young plants via Agrobacterium tumefaciens. Typical leaf symptoms and stem swelling were observed seven and eleven weeks post inoculation, respectively. Viral DNA, CSSV coat protein and virions were detected in leaves with symptoms. Agroinfected plants were used to study the in situ localization of CSSV and its histopathologic effects in planta. In both leaves and petioles, virions were only seen in the cytoplasm of phloem companion cells and of a few xylem parenchyma cells. Light microscopy showed that stem swelling results from a proliferation of the xylem, phloem and cortex cells.

Rice tungro bacilliform virus open reading frame 3 encodes a single 37-kDa coat protein.

Rice tungro bacilliform virus (RTBV) is a plant pararetrovirus and a member of the Caulimoviridae family and closely related to viruses in the Badnavirus genus. The coat protein of RTBV is part of the large polyprotein encoded by open reading frame 3 (ORF3). ORF3 of an RTBV isolate from Malaysia was sequenced (accession no. AF076470) and compared with published sequences for the region that encodes the coat protein or proteins. Molecular mass of virion proteins was determined by mass spectrometry (matrix-assisted laser desorption/ionization-TOF) performed on purified virus particles from three RTBV isolates from Malaysia. The N- and C-terminal amino acid sequences of the coat protein were deduced from the mass spectral analysis, leading to the conclusion that purified virions contain a single coat protein of 37 kDa. The location of the coat protein domain in ORF3 was reinforced as a result of immunodetection reactions using antibodies raised against six different segments of ORF3 using Western immunoblots after SDS-PAGE and isoelectrofocusing of proteins purified from RTBV particles. These studies demonstrate that RTBV coat protein is released from the polyprotein as a single coat protein of 37 kDa.

Characterization of root colonization profiles by a microcosm community of arbuscular mycorrhizal fungi using 25S rDNA-targeted nested PCR.

The aim of the present work was to study colonization patterns in roots by different arbuscular mycorrhizal fungi developing from a mixed community in soil. As different fungi cannot be distinguished with certainty in planta on the basis of fungal structures, taxon-discriminating molecular probes were developed. The 5' end of the large ribosomal subunit containing the variable domains D1 and D2 was amplified by PCR from Glomus mosseae (BEG12), G. intraradices (LPA8), Gigaspora rosea (BEG9) and Scutellospora castanea (BEG1) using newly designed eukaryote-specific primers. Sequences of the amplification products showed high interspecies variability and PCR taxon-discriminating primers were designed to distinguish between each of these four fungi. A nested PCR, using universal eukaryotic primers for the first amplification and taxon-discriminating primers for the second, was performed on individual trypan blue-stained mycorrhizal root fragments of onion and leek, and root colonization by four fungi inoculated together in a microcosm experiment was estimated. More than one fungus was detected in the majority of root fragments and all four fungi frequently co-existed within the same root fragment. Root colonization by G. mosseae and G. intraradices was similar from individual mixed inoculum, whilst the frequency of S. castanea and Gig. rosea increased in the presence of the two Glomus species, suggesting that synergistic interactions may exist between some arbuscular mycorrhizal fungi.

Mapping regions of the cauliflower mosaic virus ORF III product required for infectivity.

The open reading frame (ORF) III product (PIII) of the pararetrovirus cauliflower mosaic virus (CaMV) has nucleic acid-binding properties in vitro, but its biological role is not yet determined. ORF III is closely linked to ORF II and overlaps ORF IV out of frame in the CaMV genome. A new CaMV-derived vector (Ca delta) devoid of ORF III and containing unique restriction sites between ORFs II and IV was designed. Introduction of the wild-type CaMV ORF III into Ca delta results in a clone (Ca3) infectious in turnip plants. Truncated or point-mutated versions of ORF III were then inserted into Ca delta and tested in vivo. Inoculation of the different mutants into turnip revealed that the four C-terminal amino acid residues of PIII are dispensable for infectivity as well as an internal domain (amino acids 61 to 80). Taken together the results show that PIII possesses a functional two-domain organization. Moreover, the CaMV PIII function(s) cannot be replaced either by the PIII protein of another caulimovirus, the figwort mosaic virus, or by the P2 protein of the cacao swollen shoot badnavirus, a member of the second plant pararetrovirus group.

A short basic domain supports a nucleic acid-binding activity in the rice tungro bacilliform virus open reading frame 2 product.

Little is known about the features of badnavirus open reading frame 2 products (P2). So far, no consensus functional domain has been found in these proteins. However, they all have in common at their C-terminus amino acids which may have the capacity to bind nucleic acids. Such capacity has already been established for cacao swollen shoot virus protein P2. We have looked for such a binding capacity of rice tungro bacilliform virus (RTBV) ORF 2 product. For this purpose, the protein was expressed as full-length or truncated versions in Escherichia coli. When used in nucleic acid-binding assays, complete RTBV P2 was shown to bind both DNA and RNA. This property may be related to a basic sequence, PPKKGIKRKYPA, localized at its C-terminus. Mutations were introduced into this sequence and revealed that four of the five basic residues, including a crucial lysine, are required for the binding to nucleic acids. Moreover, this sequence can confer binding capacity when it is fused to the N-terminus of nonbinding proteins.

The open reading frame 2 product of cacao swollen shoot badnavirus is a nucleic acid-binding protein.

The function of the open reading frame 2 product (p2) of cacao swollen shoot virus (CSSV) and of other badnaviruses is not yet determined. Their carboxyl-termini are lysine and proline rich and also contain alanine residues, amino acids present at the C-termini of histone-like proteins. Full-length CSSV p2 (132 amino acids) or versions truncated at the C-terminus (128, 113, 103, or 101 amino acids) were expressed in Escherichia coli and partially purified. When assayed in nucleic acid-binding tests, p2 was able to interact with CSSV and other double-stranded DNAs and with CSSV and other single-stranded RNA transcripts in sequence-nonspecific manner. Moreover, this binding activity was progressively lost as the C-terminus was gradually deleted.