Virion stability is important for the circulative transmission of tomato yellow leaf curl sardinia virus by Bemisia tabaci, but virion access to salivary glands does not guarantee transmissibility.

The capsid protein (CP) of the monopartite begomovirus Tomato yellow leaf curl Sardinia virus (TYLCSV), family Geminiviridae, is indispensable for plant infection and vector transmission. A region between amino acids 129 and 152 is critical for virion assembly and insect transmissibility. Two previously described mutants, one with a double Q129P Q134H mutation (PNHD) and another with a further D152E change (PNHE), were found nontransmissible (NT). Another NT mutant with a single N130D change (QDQD) was retrieved from a new mutational analysis. In this study, these three NT mutants and the wild-type (wt) virus were compared in their relationships with the whitefly vector Bemisia tabaci and the nonvector Trialeurodes vaporariorum. Retention kinetics of NT mutants were analyzed by quantitative dot blot hybridization in whiteflies fed on infected plants. The QDQD mutant, whose virions appeared nongeminate following purification, was hardly detectable in either whitefly species at any sampling time. The PNHD mutant was acquired and circulated in both whitefly species for up to 10 days, like the wt virus, while PNHE circulated in B. tabaci only. Using immunogold labeling, both PNHD and PNHE CPs were detected in B. tabaci salivary glands (SGs) like the wt virus, while no labeling was found in any whitefly tissue with the QDQD mutant. Significant inhibition of transmission of the wt virus was observed after prior feeding of the insects on plants infected with the PNHE mutant, but not on plants infected with the other mutants. Virion stability and ability to cross the SG barrier are necessary for TYLCSV transmission, but interactions with molecular components inside the SGs are also critical for transmissibility.

Real-time PCR for the quantitation of Tomato yellow leaf curl Sardinia virus in tomato plants and in Bemisia tabaci.

Tomato yellow leaf curl Sardinia virus (TYLCSV) (Geminiviridae) is an important pathogen severely affecting tomato production in the Mediterranean basin. Although diagnostic protocols are available for its detection in plants and its vector Bemisia tabaci (Gennadius), suitable tools for estimating and comparing viral loads in plant and insect tissues are needed. In this paper, real-time PCR methods are described for quantitation of TYLCSV in both tomato plant and whitefly extracts. The DNA extraction method was optimised on TYLCSV-infected tomato tissue. The amount of virus was determined using specific primers and probe and standardised to the amount of DNA present in each sample, using selected endogenous tomato or Bemisia genes as internal references. The distribution of TYLCSV was relatively quantified within the four uppermost leaves of plants. An absolute estimation of the amount of TYLCSV in the first leaf below the apex was obtained. The kinetics of virus retention within different batches of viruliferous whiteflies was also analysed. The real-time PCR was 2200-fold more sensitive than membrane hybridisation, allowing detection of as few as 10 viral copies in a sample. These methods are potentially suitable for several applications, such as plant breeding for resistance, analysis of virus replication, and virus-vector interaction studies.

Field Evaluation of Tomato Hybrids Engineered with Tomato spotted wilt virus Sequences for Virus Resistance, Agronomic Performance, and Pollen-Mediated Transgene Flow.

ABSTRACT Tomato hybrids obtained from homozygous progeny of line 30-4, engineered for Tomato spotted wilt virus (TSWV) resistance, were tested under field conditions in two locations with their corresponding nontransgenic hybrids. No transgenic hybrid became infected, but 33 to 50% of plants of each nontransgenic hybrid became infected with a severe reduction of marketable fruit production. The transgenic hybrids conformed to the standard agronomic characteristics of the corresponding nontransgenic ones. Fruit were collected from the nontransgenic plots included in the experimental field and from border rows, and seed were used to estimate the flow of the transgene via pollen. No transgene flow was detected in the protected crops; however, in the open field experiment, 0.32% of tomato seedlings were found to contain the genetic modification. Immunity to TSWV infection in 30-4 hybrids was confirmed in laboratory conditions using mechanical inoculation and grafting. Thrips inoculation in leaf discs of line 30-4 demonstrated that TSWV replication was inhibited at the primary infection site but not in leaf discs of a commercial hybrid containing the naturally occurring resistance gene Sw-5. Due to the high economic value of tomato crops worldwide and the importance of TSWV, the engineered resistance described here is of practical value for breeding into cultivars of commercial interest, because it could be combined with naturally occurring resistance, thus greatly reducing the ability of the virus to develop resistance-breaking strains.

Detection of Tomato spotted wilt virus in its vector Frankliniella occidentalis by reverse transcription-polymerase chain reaction.

A method for rapid and reliable detection of Tomato spotted wilt virus (TSWV) (Tospovirus, Bunyaviridae) in its vector Frankliniella occidentalis (Thysanoptera Thripidae) would be a useful tool for studying the epidemiology of this virus. A RT-PCR method developed for this purpose is reported. The method was tested on thrips involved in laboratory transmission trials and on thrips collected in the field, whose capability to transmit TSWV was checked previously by leaf disk assays. The RT-PCR results were consistent with the results obtained by the leaf disk assays. Among thrips involved in laboratory experiments, 97% of the adults that transmitted TSWV were positive by RT-PCR; as did some non-transmitter adults reacted, whereas among field-collected thrips only the individuals able to transmit were positive by RT-PCR. In addition, healthy thrips were allowed to feed as adults on virus-infected leaves for 48 h, and then examined by RT-PCR immediately or after starving or feeding on virus-free plants for various times, to determine if virus ingested (but not transmissible) was also detectable. The virus was detectable immediately after the feed or within 12 and 24 h for individuals starved or fed on virus-free plants, respectively, but not after those periods. Thus, the method could detect rapidly and reliably the virus in vectors from the field, providing 24 h of starving to avoid positive RT-PCR results from thrips simply carrying the virus.

DNA-based methods for the detection and the identification of phytoplasmas in insect vector extracts.

DNA extraction and storage methods have been evaluated with laboratory-reared leafhoppers and/or field-collected leafhoppers and psyllids. Detection of four different phytopathogenic phytoplasmas, belonging to three taxonomic groups, has been achieved by several direct or nested polymerase chain reaction (PCR) methods with such DNA extracts. Reactions differed in both the 16/23S ribosomal primer pairs used and the specific assay and cycling conditions. Merits and possible hindrances of the various primer pairs, in relation to insect DNA extracts, are discussed. However, identification of the phytoplasma(s) necessarily relied on comparison of the polymorphism in length of the amplified DNA fragments obtained by restriction with appropriate endonucleases. Endonuclease digestion is crucial for determining the identity (subgroup affiliation) of phytoplasmas of the same groups that can be carried by an individual vector.

Estimating the number of integrations in transformed plants by quantitative real-time PCR.

BACKGROUND: When generating transformed plants, a first step in their characterization is to obtain, for each new line, an estimate of how many copies of the transgene have been integrated in the plant genome because this can deeply influence the level of transgene expression and the ease of stabilizing expression in following generations. This task is normally achieved by Southern analysis, a procedure that requires relatively large amounts of plant material and is both costly and labour-intensive. Moreover, in the presence of rearranged copies the estimates are not correct. New approaches to the problem could be of great help for plant biotechnologists. RESULTS: By using a quantitative real-time PCR method that requires limited preliminary optimisation steps, we achieved statistically significant estimates of 1, 2 and 3 copies of a transgene in the primary transformants. Furthermore, by estimating the copy number of both the gene of interest and the selectable marker gene, we show that rearrangements of the T-DNA are not the exception, and probably happen more often than usually recognised. CONCLUSIONS: We have developed a rapid and reliable method to estimate the number of integrated copies following genetic transformation. Unlike other similar procedures, this method is not dependent on identical amplification efficiency between the PCR systems used and does not need preliminary information on a calibrator. Its flexibility makes it appropriate in those situations where an accurate optimisation of all reaction components is impossible or impractical. Finally, the quality of the information produced is higher than what can be obtained by Southern blot analysis.