Evolving by deleting: patterns of molecular evolution of Apple stem pitting virus isolates from Poland.

In this study, 267 coat protein gene (CP) sequences from 48 Polish isolates of Apple stem pitting virus (ASPV) were determined. The genetic structure of the virus population was analysed and possible mechanisms of molecular evolution explored. We found evidence of recombination within the ASPV population and the presence of 17 ASPV molecular variants that differ in the length, number and arrangement of deletions in the CP. Population genetic analyses showed significant variation among isolates from pear and apple trees, between isolates from the same host species and, more interestingly, within isolates, supporting the existence of significant levels of variability within individual hosts, as expected by a quasispecies population structure. In addition, different tests support that selection might have been an important force driving diversification within isolates: positive selection was found acting upon certain amino acids. Phylogenetic analyses also showed that isolates did not classify according to the host species (pear or apple trees) but according to the pattern of deletions, suggesting a possible role for deletions during clade diversification.

Application of nucleic acid aptamers for detection of Apple stem pitting virus isolates.

DNA aptamers (PSA-H and MT32) were applied for the detection of Apple stem pitting virus (ASPV) isolates using an Enzyme-Linked Oligonucleotide Assay (ELONA) and Western blot analysis. The specificity and effectiveness of aptamers were verified in comparison to a conventional Enzyme Linked Immunosorbent Assay (ELISA). A genetically diverse group of ASPV isolates was tested. The results showed that aptamer MT32 detected a wider range of ASPV isolates than an aptamer PSA-H and proved to be superior to commercially available monoclonal antibodies. Aptamer MT32 produced higher signal intensity in ELONA with a virus-infected plant extracts than antibodies in ELISA. Moreover, the ELISA method failed to detect ASPV in six samples. The results presented in this study indicated that aptamer MT32 can be used as a receptor molecule of various immunoassay protocols for ASPV detection.

Autoimmune premature ovarian failure.

Premature ovarian failure (POF), also termed as primary ovarian insufficiency (POI), is a highly heterogenous condition affecting 0.5-3.0% of women in childbearing age. These young women comprise quite a formidable group with unique physical and psychological needs that require special attention. Premature ovarian senescence (POS) in all of its forms evolves insidiously as a basically asymptomatic process, leading to complete loss of ovarian function, and POI/POF diagnoses are currently made at relatively late stages. Well-known and well-documented risk factors exist, and the presence or suspicion of autoimmune disorder should be regarded as an important one. Premature ovarian failure is to some degree predictable in its occurrence and should be considered while encountering young women with loss of menstrual regularity, especially when there is a concomitant dysfunction in the immune system.

Simultaneous detection of Cherry necrotic rusty mottle virus and Cherry green ring mottle virus using real-time PCR and high resolution melting analysis.

In this study, the real-time PCR assays were combined with high resolution melting (HRM) analysis for the simultaneous detection of Cherry necrotic rusty mottle virus (CNRMV) and Cherry green ring mottle virus (CGRMV) infection in sweet cherry trees. Detection of CNRMV and CGRMV was performed in a real-time PCR using a primer set for both of them or duplex real-time PCR that included one specific primer set for each virus. These two strategies allowed us to confirmed virus infection in all tested samples. In 17 field samples the technique revealed samples positive for CNRMV or CGRMV as well as positive for both viruses. In addition, the HRM analysis made it possible to differentiate clearly between CNRMV and CGRMV. Sequence variations among CNRMV and CGRMV isolates observed from the HRM peaks were confirmed by sequencing. To test the capability to use this method in field, forty one sweet cherry samples were examined by HRM analysis. The HRM data showed that seven samples were positive for CNRMV and three were infected with CGRMV. The results presented in this study indicated that real-time PCR followed by HRM analysis provides sensitive, automated and rapid tool to detect and differentiate between CNRMV and CGRMV isolates.

A new method for detection and discrimination of Pepino mosaic virus isolates using high resolution melting analysis of the triple gene block 3.

Diagnostic methods distinguished different Pepino mosaic virus (PepMV) genotypes but the methods do not detect sequence variation in particular gene segments. The necrotic and non-necrotic isolates (pathotypes) of PepMV share a 99% sequence similarity. These isolates differ from each other at one nucleotide site in the triple gene block 3. In this study, a combination of real-time reverse transcription polymerase chain reaction and high resolution melting curve analysis of triple gene block 3 was developed for simultaneous detection and differentiation of PepMV pathotypes. The triple gene block 3 region carrying a transition A → G was amplified using two primer pairs from twelve virus isolates, and was subjected to high resolution melting curve analysis. The results showed two distinct melting curve profiles related to each pathotype. The results also indicated that the high resolution melting method could readily differentiate between necrotic and non-necrotic PepMV pathotypes.

Sequence diversity and potential recombination events in the coat protein gene of Apple stem pitting virus.

The variability of the Apple stem pitting virus (ASPV) coat protein (CP) gene was investigated. The CP gene of ten virus isolates from apple and pear trees was sequenced. Comparison of all sequenced virus isolates revealed high diversity of the CP gene (70.7-93.5% at the nucleotide level and 77.8-98.7% at the amino acid level). Additionally, one or two deletions in the N-terminal part of the coat protein gene of the studied virus isolates were identified. The ratio of nonsynonymous to synonymous polymorphic sites indicated that purifying selection has acted to eliminate deleterious mutations in coding sites. Moreover, the evidences for recombination in analyzed sequences were provided. It is likely that recombination, along with selection, enhances the speed of elimination of deleterious mutations in ASPV, following the mutational deterministic hypothesis of Kondrashov.

Selection and versatile application of virus-specific aptamers.

Although the significance of molecular diagnostics in routine plant virus detection is rapidly growing, the preferred methods are still antibody-based enzyme immunoassays. In the past decade, aptamers have been demonstrated to be viable alternatives of antibodies in many applications. We set out to select apple stem pitting virus (ASPV)-specific aptamers and to apply them as antibody substitutes in various immunoassay methods. The applied systematic evolution of ligands by exponential enrichment (SELEX) procedure resulted in highly discriminative aptamers selectively binding to the target virus coat protein even in complex protein matrixes. We developed protocols for exploitation of aptamers in diverse plant virus diagnosis methods, such as dot and Western blot analyses and enzyme-linked oligonucleotide assay (ELONA). Our selected aptamers proved to be superior to the available antibody in all aspects. In contrast to the antibody, the aptamers decorate both native and denaturated proteins, and ELONA produces higher signal intensity than traditional enzyme-linked immunosorbent assay (ELISA) with virus-infected plant extract. Summarily, our results present the selection and practical utilization of first plant virus-specific aptamers. Most important, the first application of ELONA for virus detection is demonstrated, which proposes a novel, more flexible, and cost-effective means of virus diagnostics.