Robust detection and identification of multiple oomycetes and fungi in environmental samples by using a novel cleavable padlock probe-based ligation detection assay.

Simultaneous detection and identification of multiple pathogenic microorganisms in complex environmental samples are required in numerous diagnostic fields. Here, we describe the development of a novel, background-free ligation detection (LD) system using a single compound detector probe per target. The detector probes used, referred to as padlock probes (PLPs), are long oligonucleotides containing asymmetric target complementary regions at both their 5' and 3' ends which confer extremely specific target detection. Probes also incorporate a desthiobiotin moiety and an internal endonuclease IV cleavage site. DNA samples are PCR amplified, and the resulting products serve as potential targets for PLP ligation. Upon perfect target hybridization, the PLPs are circularized via enzymatic ligation, captured, and cleaved, allowing only the originally ligated PLPs to be visualized on a universal microarray. Unlike previous procedures, the probes themselves are not amplified, thereby allowing a simple PLP cleavage to yield a background-free assay. We designed and tested nine PLPs targeting several oomycetes and fungi. All of the probes specifically detected their corresponding targets and provided perfect discrimination against closely related nontarget organisms, yielding an assay sensitivity of 1 pg genomic DNA and a dynamic detection range of 10(4). A practical demonstration with samples collected from horticultural water circulation systems was performed to test the robustness of the newly developed multiplex assay. This novel LD system enables highly specific detection and identification of multiple pathogens over a wide range of target concentrations and should be easily adaptable to a variety of applications in environmental microbiology.

Accurate quantification of microorganisms in PCR-inhibiting environmental DNA extracts by a novel internal amplification control approach using Biotrove OpenArrays.

PCR-based detection assays are prone to inhibition by substances present in environmental samples, thereby potentially leading to inaccurate target quantification or false-negative results. Internal amplification controls (IACs) have been developed to help alleviate this problem but are generally applied in a single concentration, thereby yielding less-than-optimal results across the wide range of microbial gene target concentrations possible in environmental samples (J. Hoorfar, B. Malorny, A. Abdulmawjood, N. Cook, M. Wagner, and P. Fach, J. Clin. Microbiol. 42:1863-1868, 2004). Increasing the number of IACs for each quantitative PCR (qPCR) sample individually, however, typically reduces sensitivity and, more importantly, the reliability of quantification. Fortunately, current advances in high-throughput qPCR platforms offer the possibility of multiple reactions for a single sample simultaneously, thereby allowing the implementation of more than one IAC concentration per sample. Here, we describe the development of a novel IAC approach that is specifically designed for the state-of-the-art Biotrove OpenArray platform. Different IAC targets were applied at a range of concentrations, yielding a calibration IAC curve for each individual DNA sample. The developed IACs were optimized, tested, and validated by using more than 5,000 unique qPCR amplifications, allowing accurate quantification of microorganisms when applied to soil DNA extracts containing various levels of PCR-inhibiting compounds. To our knowledge, this is the first study using a suite of IACs at different target concentrations to monitor PCR inhibition across a wide target range, thereby allowing reliable and accurate quantification of microorganisms in PCR-inhibiting DNA extracts. The developed IAC is ideally suited for high-throughput screenings of, for example, ecological and agricultural samples on next-generation qPCR platforms.

A soluble factor and GTP gamma S are required for Dictyostelium discoideum guanylate cyclase activity.

Amoeba of Dictyostelium discoideum show a rapid, transient cGMP synthesis in response to chemotactic stimulation. Using Mg(2+)-GTP as a substrate, guanylate cyclase (E.C. 4.6.1.2.) activity is found exclusively in the particulate fraction of Dictyostelium cells. Here we show that the activity is dependent on the presence of the non-hydrolysable GTP-analogue GTP gamma S, which itself is only a poor substrate for the enzyme under the prevailing conditions. Evidence is presented that a transient exposure of the enzyme to GTP gamma S is sufficient to constitutively activate the enzyme. GTP gamma S-dependent activity is found to require a factor that can be separated from the enzyme by washing the particulate fraction with low salt buffer. Addition of the soluble cell fraction to these washed membranes restores enzyme activity.

Development of a multiplex AmpliDet RNA assay for simultaneous detection and typing of potato virus Y isolates.

A multiplex AmpliDet RNA assay was developed for the specific detection of potato virus Y (PVY), and for the differentiation of the PVY(N), PVY(O/C) strains and the tuber necrotic isolates (PVY(NTN)). The assay is based on the generic amplification of a region within the coat protein coding region of all known PVY isolates by nucleic acid sequence-based amplification (NASBA) and strain-specific detection by molecular beacons. PVY(NTN)-specific diagnosis is achieved by detecting PVY(N) and PVY(O)-specific sequences flanking a recombination site that is associated with the tuber necrotic pathotype. The assay exhibited good specificity toward the various PVY strains in both single and mixed infections. The technique was validated by the use of 47 PVY isolates originating from six countries. The results of the AmpliDet RNA assay were identical or consistent with those of biological characterisation in the decisive majority of cases.

Development of a multiplex AmpliDet RNA for the simultaneous detection of Potato leafroll virus and Potato virus Y in potato tubers.

A novel isothermal multiplex AmpliDet RNA system is described for the simultaneous amplification and detection of Potato leafroll virus (PLRV) and Potato virus Y (PVY) in seed potatoes. The risk of contamination by carry-over during diagnostic screening is eliminated by performing the reaction in a single closed tube. The viruses present in a sample are identified using differently coloured molecular beacons directed to a selected virus-specific sequence within the amplicon formed during amplification. With this system, as little as 10 fg of purified PLRV or PVY can be detected. The presence of both viruses in a sample is detected by the multiplex assay within a high range of virus concentrations. The reliability of the multiplex assay was compared with the enzyme-linked immunosorbent assay for detection of PLRV- or PVY-antigens in potato tubers. The multiplex assay detected clearly the viruses present originally in the potato tubers in all samples, demonstrating its potential for routine diagnostic work and high-throughput screening.

Direct detection of potato leafroll virus in potato tubers by immunocapture and the isothermal nucleic acid amplification method NASBA.

NASBA, an isothermal amplification method for nucleic acids, was applied to the detection of RNA of potato leafroll virus (PLRV) in a single enzymatic reaction at 41 degrees C. A set of primers was selected from the coat protein open reading frame sequence of PLRV to allow amplification of viral RNA. The NASBA reaction products were visualized after electrophoresis by ethidium bromide or acridine orange staining. The specificity of the amplification products was validated by Northern blot analysis with a PLRV-specific 32P-labelled oligonucleotide probe. The procedure was coupled to immunocapture of PLRV virions from tuber extracts by immobilized antibodies in microtubes. It was possible to discriminate readily by this method between uninfected and primarily PLRV-infected potato tubers. NASBA is suitable for the direct detection of PLRV in potato tubers from primarily infected plants, offering the potential to considerably simplify the inspection of seed-potatoes for virus infection.

Multiplex RT-PCR detection of four aphid-borne strawberry viruses in Fragaria spp. in combination with a plant mRNA specific internal control.

The principal aphid-borne viruses infecting Strawberry (Fragaria spp.) Strawberry crinkle virus (SCV), Strawberry mild yellow edge virus (SMYEV), Strawberry mottle virus (SMoV) and Strawberry vein banding virus (SVBV) can cause serious crop losses. In this paper, a multiplex reverse transcriptase polymerase chain reaction (RT-PCR) method is described for the simultaneous detection of all four viruses in combination with a plant mRNA specific internal control which can be used as an indicator of the effectiveness of the extraction and RT-PCR. In total, 18 strawberry isolates infected naturally were analysed by this method. Every combination of RNA virus was able to be detected and a full complement of all four viruses were found together in three isolates, all taken from wild strawberry (Fragaria chiloensis (L.) Duch.) in Chile. The upper detection limit for the four viruses was at an extract dilution of 1/200. The broad applicability of the RNA specific internal control primers-which produced a PCR fragment of the expected size in 25 of 27 plant species tested-combined with improvements, made in extraction methods described provides potentially a standard method for comparable RT-PCR analyses in a wide variety of plant species.

Rapid and Sensitive Detection of Apple stem pitting virus in Apple Trees Through RNA Amplification and Probing with Fluorescent Molecular Beacons.

ABSTRACT Currently, detection of Apple stem pitting virus (ASPV; genus Foveavirus) in apple trees for certification purposes occurs by woody indexing. This method requires a minimum of 12 to 24 weeks in greenhouse testing to up to 2 years in field testing. In this paper, the development of a single tube AmpliDet RNA system for the rapid gel-free detection of ASPV in apple tree tissues is described. The system relies on the specific amplification of the viral RNA by nucleic acid sequence-based amplification and the simultaneous fluorescent detection of the amplification product through molecular beacons. A sensitivity of a minimum of 100 molecules of transcript RNA was obtained by the ASPV-specific AmpliDet RNA. All biologically characterized ASPV isolates from a field trial and 12 of 14 isolates from a plant virus collection were readily detected with this AmpliDet RNA system. In addition, the efficiency of this method for detecting ASPV in 'Golden Delicious' and 'Gravenstein' apple trees was compared throughout the year with mechanical inoculation onto Nicotiana occidentalis 37B, a candidate indicator for ASPV. This revealed that only AmpliDet RNA consistently detected the virus in bark tissue, irrespective of the season. Season-specific tissues such as buds, petals, and fruits, but not leaves, also were reliable sources for detection of ASPV by the AmpliDet RNA system.

Regulation of adenylate cyclase in electropermeabilized Dictyostelium discoideum cells.

In Dictyostelium discoideum cells the enzyme adenylate cyclase is functionally coupled to cell surface receptors for cAMP. Coupling is known to involve one or more G-proteins. Receptor-mediated activation of adenylate cyclase is subject to adaptation. In this study we employ an electropermeabilized cell system to investigate regulation of D. discoideum adenylate cyclase. Conditions for selective permeabilization of the plasma membrane have been described by C.D. Schoen, J. C. Arents, T. Bruin, and R. Van Driel (1989, Exp. Cell Res. 181, 51-62). Only small pores are created in the membrane, allowing exchange of exclusively low molecular weight substances like nucleotides, and preventing the loss of macromolecules. Under these conditions functional protein-protein interactions are likely to remain intact. Adenylate cyclase in permeabilized cells was activated by the cAMP receptor agonist 2'-deoxy cAMP and by the nonhydrolyzable GTP-analogue GTP gamma S, which activates G-proteins. The time course of the adenylate cyclase reaction in permeabilized cells was similar to that of intact cells. Maximal adenylate cyclase activity was observed if cAMP receptor agonist or GTP-analogue was added just before cell permeabilization. If these activators were added after permeabilization adenylate cyclase was stimulated in a suboptimal way. The sensitivity of adenylate cyclase activity for receptor occupation was found to decay more rapidly than that for G-protein activation. Importantly, the adenylate cyclase reaction in permeabilized cells was subject to an adaptation-like process that was characterized by a time course similar to adaptation in vivo. In vitro adaptation was not affected by cAMP receptor agonists or by G-protein activation. Evidently electropermeabilized cells constitute an excellent system for investigating the positive and negative regulation of D. discoideum adenylate cyclase.

Characterization and complete nucleotide sequence of Strawberry mottle virus: a tentative member of a new family of bipartite plant picorna-like viruses.

An isolate of Strawberry mottle virus (SMoV) was transferred from Fragaria vesca to Nicotiana occidentalis and Chenopodium quinoa by mechanical inoculation. Electron micrographs of infected tissues showed the presence of isometric particles of approximately 28 nm in diameter. SMoV-associated tubular structures were also conspicuous, particularly in the plasmodesmata of C. quinoa. DsRNA extraction of SMoV-infected N. occidentalis yielded two bands of 6.3 and 7.8 kbp which were cloned and sequenced. Gaps in the sequence, including the 5' and 3' ends, were filled using RT-PCR and RACE. The genome of SMoV was found to consist of RNA1 and RNA2 of 7036 and 5619 nt, respectively, excluding a poly(A) tail. Each RNA encodes one polyprotein and has a 3' non-coding region of approximately 1150 nt. The polyprotein of RNA1 contains regions with identities to helicase, viral genome-linked protein, protease and polymerase (RdRp), and shares its closest similarity with RNA1 of the tentative nepovirus Satsuma dwarf virus (SDV). The polyprotein of RNA2 displayed some similarity to the large coat protein domain of SDV and related viruses. Phylogenetic analysis of the RdRp region showed that SMoV falls into a separate group containing SDV, Apple latent spherical virus, Naval orange infectious mottling virus and Rice tungro spherical virus. Given the size of RNA2 and the presence of a long 3' non-coding region, SMoV is more typical of a nepovirus, although atypically for a nepovirus it is aphid transmissible. We propose that SMoV is a tentative member of an SDV-like lineage of picorna-like viruses.

Intracellular localization of secretable cAMP in relaying Dictyostelium discoideum cells.

Dictyostelium discoideum cells synthesize and secrete the chemoattractant cAMP within minutes after chemotactic stimulation. During development, this signal-relay process is instrumental in cell aggregation, pattern formation, and differentiation. Cyclic AMP is known to accumulate inside the cell before secretion. In this study we investigated the subcellular localization of the nascent cAMP. After chemotactic stimulation at 0 degrees C and subsequent accumulation of intracellular cAMP, the newly synthesized chemoattractant could be released by gently opening cells in two different ways. Both methods make the cytosolic compartment accessible, whereas intracellular compartments surrounded by a membrane remain largely intact. The first method involved rapid lysis by forced passage through a 5-micron pore-size Nuclepore filter. The second technique was electropermeabilization under carefully controlled conditions that ensured the formation of small, stable pores in the plasma membrane. These pores allowed the passage of small molecules, such as cAMP, but not of macromolecules. To confirm the selectivity for the plasma membrane of both methods, we showed that a typical vesicular cell compartment, the lysosome, remained intact. Both procedures immediately released all intracellularly accumulated cAMP. We interpret our results as strong evidence for accumulation of nascent cAMP in the cytosolic compartment rather than in a vesicular compartment before it is secreted. This implies that cAMP secretion takes place via a trans-membrane transport mechanism, rather than by exocytosis.

Guanylate cyclase activity in permeabilized Dictyostelium discoideum cells.

Dictyostelium discoideum cells respond to chemoattractants by transient activation of guanylate cyclase. Cyclic GMP is a second messenger that transduces the chemotactic signal. We used an electropermeabilized cell system to investigate the regulation of guanylate cyclase. Enzyme activity in permeabilized cells was dependent on the presence of a nonhydrolysable GTP analogue (e.g., GTP gamma S), which could not be replaced by GTP, GDP, or GMP. After the initiation of the guanylate cyclase reaction in permeabilized cells only a short burst of activity is observed, because the enzyme is inactivated with a t1/2 of about 15 s. We show that inactivation is not due to lack of substrate, resealing of the pores in the cell membrane, product inhibition by cGMP, or intrinsic instability of the enzyme. Physiological concentrations of Ca2+ ions inhibited the enzyme (half-maximal effect at 0.3 microM), whereas InsP3 had no effect. Once inactivated, the enzyme could only be reactivated after homogenization of the permeabilized cells and removal of the soluble cell fraction. This suggests that a soluble factor is involved in an autonomous process that inactivates guanylate cyclase and is triggered only after the enzyme is activated. The initial rate of guanylate cyclase activity in permeabilized cells is similar to that in intact, chemotactically activated cells. Moreover, the rate of inactivation of the enzyme in permeabilized cells and that due to adaptation in vivo are about equal. This suggests that the activation and inactivation of guanylate cyclase observed in this permeabilized cell system is related to that of chemotactic activation and adaptation in intact cells.

Molecular beacon probes combined with amplification by NASBA enable homogeneous, real-time detection of RNA.

Molecular beacon probes can be employed in a NASBA amplicon detection system to generate a specific fluorescent signal concomitantly with amplification. A molecular beacon, designed to hybridize within the target sequence, was introduced into NASBA reactions that amplify the genomic RNA of potato leafroll virus (PLRV). During amplification, the probe anneals to the antisense RNA amplicon generated by NASBA, producing a specific fluorescent signal that can be monitored in real-time. The assay is rapid, sensitive and specific. As RNA amplification and detection can be carried out in unopened vessels, it minimizes the risk of carry-over contaminations. Robustness has been verified on real-world samples. This homogeneous assay, called AmpliDet RNA, is a significant improvement over current detection methods for NASBA amplicons and is suitable for one-tube applications ranging from high-throughput diagnostics to in vivo studies of biological activities.