Sensitive detection of potato spindle tuber and temperate fruit tree viroids by reverse transcription-polymerase chain reaction-probe capture hybridization

An Inside Look into Biological Miniatures: Molecular Mechanisms of Viroids

Viroids are tiny single-stranded circular RNA pathogens that infect plants. Viroids do not encode any proteins, yet cause an assortment of symptoms. The following review describes viroid classification, molecular biology and spread. The review also discusses viroid pathogenesis, host interactions and detection. The review concludes with a description of future prospects in viroid research.

Interference between variants of peach latent mosaic viroid reveals novel features of its fitness landscape: implications for detection

Natural populations of peach latent mosaic viroid (PLMVd) are complex mixtures of variants. During routine testing, TaqMan rtRT-PCR and RNA gel-blot hybridization produced discordant results with some PLMVd isolates. Analysis of the corresponding populations showed that they were exclusively composed of variants (of class II) with a structural domain different from that of the reference and many other variants (of class I) targeted by the TaqMan rtRT-PCR probe. Bioassays in peach revealed that a representative PLMVd variant of class II replicated without symptoms, generated a progeny with low nucleotide diversity, and, intriguingly, outcompeted a representative symptomatic variant of class I when co-inoculated in equimolecular amounts. A number of informative positions associated with the higher fitness of variants of class II have been identified, and novel sets of primers and probes for universal or specific TaqMan rtRT-PCR detection of PLMVd variants have been designed and tested.

Application of PCR-ELISA in molecular diagnosis

Polymerase chain reaction-enzyme linked immunosorbent assay (PCR-ELISA) is an immunodetection method that can quantify PCR product directly after immobilization of biotinylated DNA on a microplate. This method, which detects nucleic acid instead of protein, is a much more sensitive method compared to conventional PCR method, with shorter analytical time and lower detection limit. Its high specificity and sensitivity, together with its semiquantitative ability, give it a huge potential to serve as a powerful detection tool in various industries such as medical, veterinary, and agricultural industries. With the recent advances in PCR-ELISA, it is envisaged that the assay is more widely recognized for its fast and sensitive detection limit which could improve overall diagnostic time and quality.

Sensitive and rapid detection of peach latent mosaic viroid by the reverse transcription loop-mediated isothermal amplification

A reverse transcription loop-mediated isothermal amplification (RT-LAMP) method for the detection of peach latent mosaic viroid (PLMVd) was developed. Four primer sets (OLD, OLD1, NEW, and Fukuta's) were designed originally. Based on initial experiments the set OLD1 was selected for further evaluation. Simple and accelerated RT-LAMP was preformed using degenerate and no degenerate forward-loop (F-loop) and backward-loop (B-Loop) primers. Degenerate primers were selected, and after determination of their best concentration (0.8microM), the reaction was preformed at different temperatures (60-67.5 degrees C) using three different betaine concentrations (0.8M, 0.4M, and 0.2M). Optimal conditions were found to be 62.5 degrees C and 0.8M betaine. Under these conditions, using tRNA as template, PLMVd was detected within only 32min, compared to 180min of RT-PCR, using the Real Time Turbimeter (LA200, Teramecs) which measures the turbidity caused by the production of insoluble magnesium pyrophosphate. In addition, RT-LAMP was more sensitive than RT-PCR. PLMVd was detected in peach, plum, apricot, pear, wild pear and quince samples.

Construction of a multiprobe for the simultaneous detection of viroids infecting citrus trees

Infections with different viroid species are common among cultivated fruit trees and grapevines, and many old-clone citrus varieties contain up to five citrus viroids (CVds) within a single tree. This paper describes the construction of a CVd-Multiprobe consisting of full-length clones of Hop stunt viroid, Citrus exocortis viroid, Citrus bent leaf viroid and CVd-III. The CVd-Multiprobe was tested against RNA transcripts of the four viroids and RNA extracts from plants singly infected with CEVd or HSVd or multiply infected with different CVds. The viroids were effectively diagnosed with the DIG labeled CVd-Multiprobe when tested by Northern hybridization or dot blot analyses. The CVd-Multiprobe does not provide information on the specific viroid resulting in a positive signal. However, this should not be considered as a problem, since most citrus certification programs will discard budwood source trees infected with any of the known CVds.

Development of a one tube-one step RT-PCR protocol for the detection of seven viroids in four genera: Apscaviroid, Hostuviroid, Pelamoviroid and Pospiviroid

A one tube-one step RT-PCR was developed for the detection of seven viroids (Apple scar skin viroid, Apple dimple fruit viroid, Pear blister canker viroid, Hop stunt viroid, Chrysanthemum stunt viroid, Citrus exocortis viroid and Peach latent mosaic viroid) in four genera that infect eight plant species. The efficiency and specificity of this method were optimized by the use of Moloney-murine leukemia virus (M-MLV) reverse-transcriptase and HotStarTaq DNA polymerase which allowed increase sensitivity of viroid detection. The method was assessed with 56 viroid-infected field plants. The multiplex one tube-one step RT-PCR has the advantage of requiring less hands-on time to set up an assay than standard multiplex one, it also reduces the possibility of false positive tests because all steps are performed in the same tube thus, avoiding cross-contamination. The method may be used routinely for viroid detection in sanitary and certification programmes.

Multiplex RT-PCR-ELISA compared with bioassay for the detection of four apple viruses

A sensitive and reliable multiplex RT-PCR-ELISA technique for the detection of Apple chlorotic leaf spot virus, Apple stem pitting virus, Apple mosaic virus and Apple stem grooving virus was developed. This technique is compared with the method used commonly for indexing by woody indicators, which is time consuming and expensive. For the RT-PCR-ELISA technique, the amplified products were labeled with digoxigenin during the RT-PCR by incorporation of a digoxigenin labeled primer. After hybridization of the PCR products to specific capture oligonucleotides, which were bound covalently to the surface of NucleoLink strips, anti-digoxigenin antibodies were used for detection. More than 100 samples were tested in parallel by indexing and multiplex-RT-PCR-ELISA. All infections detected by woody indicators were also detected by multiplex RT-PCR-ELISA. Furthermore, additional infections were only found by multiplex RT-PCR-ELISA. The colourimetric detection of multiplex-RT-PCR products was at least as sensitive and sometimes slightly more sensitive than detection by gel electrophoresis. The results show that this molecular technique is more reliable for the detection of the above mentioned apple viruses than indexing by woody indicators, thereby helping to reduce cost and time during the certification of plant material.

Expression of a novel immunoglobulin gene SNC73 in human cancer and non-cancerous tissues

AIM: To investigate the expression of immunoglobulin gene SNC73 in malignant tumors and non-cancerous normal tissues.

METHODS: Expression level of SNC73 in tumors and non-cancerous tissues from the same patient was determined by reverse transcription polymerase chain reaction and enzyme-linked immunosorbent assay (RT-PCR-ELISA) in 90 cases of malignant tumors, including colorectal cancer, gastric cancer, breast cancer, lung cancer and liver cancer. Analysis on the correlation of SNC73 expression with sex, age, site, grade of differentiation, depth of invasion, and metastases in colorectal cancer patients was made.

RESULTS: Expression level of SNC73 in non-cancerous colorectal mucosa and colorectal cancerous tissues was 1.234 ± 0.842 and 0.737 ± 0.731, respectively (P < 0.01), with the mean ratio of 7.134 ± 14.092 (range, 0.36-59.54). Expression of SNC73 showed no significant difference among gastric cancer, breast cancer, lung cancer and liver cancer when compared with non-cancerous tissues (P > 0.05). No correlation was found between SNC73 expression level and various clinicopathological factors, including sex, age, site, grade of differentiation, depth of invasion and metastases of CRC patients.

CONCLUSION: Down-regulation of SNC73 expression may be a relatively specific phenomenon in colorectal cancer. SNC73 is a potential genetic marker for the carcinongenesis of colorectal cancer. The relationship of SNC73 expression and carcinogenesis of colorectal cancer merits further study.

Evaluation of four template preparation methods for polymerase chain reaction-based detection of Salmonella in ground beef and chicken

AIMS

To compare procedures for recovering template DNA from ground beef or chicken for polymerase chain reaction (PCR)-based detection of Salmonella.

METHODS AND RESULTS

The primer set of ST11 and ST15 was utilized to amplify a 429-bp product from Salmonella serotype Typhimurium. Boiling and three commercial kits were evaluated for extracting DNA from pure suspensions and artificially contaminated ground beef and chicken. The detection sensitivity of the PCR assay for pure cultures was independent of the template preparation method (P=0.946). Boiling and GeneReleaser failed to detect Salm. Typhimurium at 4 x 106 cfu g(-1) in ground chicken. PrepMan Ultra and the high pure PCR template preparation kit facilitated reliable and sensitive detection of Salm. Typhimurium in two types of food. The sensitivities were approx. 4 x 103 cfu g(-1). When spiked samples were enriched in peptone water for 6 h, an initial inoculum of 1 cfu g(-1) was detectable.

CONCLUSIONS

Four template DNA preparation methods differed in performance with respect to the type of samples tested.

SIGNIFICANCE AND IMPACT OF THE STUDY

Template DNA for the PCR detection of pathogenic bacteria, such as Salmonella in meat and poultry, could be effectively obtained using a simple rapid method such as the commercially available PrepMan Ultra kit.

Molecular diagnostics for fungal plant pathogens

Accurate identification of fungal phytopathogens is essential for virtually all aspects of plant pathology, from fundamental research on the biology of pathogens to the control of the diseases they cause. Although molecular methods, such as polymerase chain reaction (PCR), are routinely used in the diagnosis of human diseases, they are not yet widely used to detect and identify plant pathogens. Here we review some of the diagnostic tools currently used for fungal plant pathogens and describe some novel applications. Technological advances in PCR-based methods, such as real-time PCR, allow fast, accurate detection and quantification of plant pathogens and are now being applied to practical problems. Molecular methods have been used to detect several pathogens simultaneously in wheat, and to study the development of fungicide resistance in wheat pathogens. Information resulting from such work could be used to improve disease control by allowing more rational decisions to be made about the choice and use of fungicides and resistant cultivars. Molecular methods have also been applied to the study of variation in plant pathogen populations, for example detection of different mating types or virulence types. PCR-based methods can provide new tools to monitor the exposure of a crop to pathogen inoculum that are more reliable and faster than conventional methods. This information can be used to improve disease control decision making. The development and application of molecular diagnostic methods in the future is discussed and we expect that new developments will increase the adoption of these new technologies for the diagnosis and study of plant disease.

A novel multiplex RT-PCR probe capture hybridization (RT-PCR-ELISA) for simultaneous detection of six viroids in four genera: Apscaviroid, Hostuviroid, Pelamoviroid, and Pospiviroid

A rapid and sensitive assay was developed for the detection and identification of viroids by standard or multiplex reverse transcription-polymerase chain reaction (RT-PCR)-probe capture hybridization (RT-PCR-ELISA). The assay was applied successfully for the detection and identification of the following six viroid species from infected tissues: Potato spindle tuber viroid (Pospiviroid), Peach latent mosaic viroid (Pelamoviroid), Apple scar skin viroid (Apscaviroid), Apple dimple fruit viroid (Apscaviroid), Pear blister canker viroid (Apscaviroid), and Hop stunt viroid (Hostuviroid). Total RNA was obtained from infected tissue by the Qiagen RNeasy kit and, then viroid cDNA was synthesized using viroid specific complementary DNA primer. To identify and differentiate the amplicons of the six viroids, each amplicon was digoxigenin (DIG)-labelled during the amplification process, and then detected by a colorimetric system using a biotinylated cDNA capture probe specific for each viroid. The results revealed that each capture probe hybridized only to its complementary DIG-labelled amplicon. Thus the six viroids can be detected and differentiated in a multiplex RT-PCR-ELISA assay. In the multiplex assay, cDNAs of six viroids were synthesized simultaneously in one tube, DIG-labelled during amplification, then a portion of the DIG-labelled amplified products was hybridized with selected capture probe. All the six viroid capture probes hybridized to their respective complementary DIG-labelled RT-PCR-amplified product. These findings are important for viroid detection and identification for studying host-viroid interactions and for management and control viroid diseases.

Highly sensitive one-tube RT-PCR and microplate hybridisation assay for the detection and for the discrimination of classical swine fever virus from other pestiviruses

Rapid, sensitive and specific laboratory diagnostic methods are necessary to confirm outbreaks of classical swine fever. The detection of classical swine fever virus (CSFV) and its discrimination from other pestiviruses can be achieved by virus isolation on cell culture, antigen detection, or molecular methods. To reduce the time and the number of steps in the diagnostic procedure a sensitive and rapid detection method based on specific amplification of the pestiviral RNA by one-step reverse transcription-polymerase chain reaction (RT-PCR) followed by detection and differentiation of the amplification products by pestivirus-, bovine viral diarrhoea virus- (BVDV-) and CSFV-specific capture probe hybridisation and colorimetric assay in microwell plates (enzyme liked immunosorbent assay (ELISA)) was developed. Two different methods using two gene regions for pestivirus RT-PCR amplification were carried out. One pair of primers was selected from the 5'-UTR region and the second one from the gene region coding for N(pro), C and E0 proteins. The designed oligonucleotide primers were used for several pestivirus reference strains as well as for some field isolates detection in cell culture supernatants and in clinical specimens. The specificity and sensitivity of both methods were compared using EZ rTth RNA PCR kit and ACCESS RT-PCR system for combined RT-PCR assay. The use of one-step RT-PCR eliminates the additional manipulations that are generally required for a two reaction system and limits the risk of carry-over contamination. Labelling of PCR products with digoxigenin (DIG) during the amplification reaction enables colorimetric assessment of hybridisation reactions. For solution hybridisation pestivirus-, BVDV- and CSFV-specific biotin-labelled capture probes were used. By serial dilutions of DIG-labelled PCR products the RT-PCR-ELISA was found to be 100-times more sensitive than the conventional agarose gel electrophoresis. Higher sensitivity of RT-PCR-ELISA detection using specific biotin-labelled probes offers the opportunity to eliminate strain specific nested PCR and to overcome the problems with contamination and false positive results.

Sensitive detection of the Egyptian species of sugarcane streak virus by PCR-probe capture hybridization (PCR-ELISA) and its complete nucleotide sequence

A rapid and sensitive assay for the specific detection of Sugarcane streak virus (SSV) using PCR-probe capture hybridization (PCR-ELISA) was developed. Nucleic acids suitable for PCR were extracted from SSV-infected tissue using organic solvents or Fast DNA kit. SSV cDNA was amplified using viral specific primers and the amplified SSV cDNA (amplicon) was DIG-labelled during the amplification process. The amplicon was then detected in a colorimetric hybridization system by a microtiter plate using a biotinylated cDNA (22 nt), cDNA (789 nt) or cRNA (789 nt) capture probe. This system combines the specificity of molecular hybridization, the ease of the colorimetric protocol, and is 10-100 fold more sensitive than agarose gel electrophoretic analysis in detecting the amplified product. Long cDNA or cRNA capture probe was 2-7 fold more sensitive than the oligo cDNA probe for the detection. Complete nucleotide sequence of SSV from Naga Hammady, Egypt, revealed that SSV-EG is a new species of SSV that shares 66% nucleotide identity with the virus species from Natal, South Africa.

Impacts of Molecular Diagnostic Technologies on Plant Disease Management

Detection and diagnosis of plant viruses has included serological laboratory tests since the 1960s. Relatively little work was done on serological detection of plant pathogenic bacteria and fungi prior to the development of ELISA and monoclonal antibody technologies. Most applications for laboratory-based tests were directed at virus detection with relatively little emphasis on fungal and bacterial pathogens, though there was some good work done with other groups of plant pathogens. With the advent of molecular biology and the ability to compare regions of genomic DNA representing conserved sequences, the development of laboratory tests increased at an amazing rate for all groups of plant pathogens. Comparison of ITS regions of bacteria, fungi, and nematodes has proven useful for taxonomic purposes. Sequencing of conserved genes has been used to develop PCR-based detection with varying levels of specificity for viruses, fungi, and bacteria. Combinations of ELISA and PCR technologies are used to improve sensitivity of detection and to avoid problems with inhibitors or PCR often found in plants. The application of these technologies in plant pathology has greatly improved our ability to detect plant pathogens and is increasing our understanding of, their ecology and epidemiology.