Development of conventional and real-time NASBA for the detection of Legionella species in respiratory specimens

Isothermal nucleic acid sequence-based amplification (NASBA) was applied to detect Legionella 16S rRNA. The assay was originally developed as a Legionella pneumophila conventional NASBA assay with electrochemiluminescence (ECL) detection and was subsequently adapted to a L. pneumophila real-time NASBA format and a Legionella spp. real-time NASBA using molecular beacons. L. pneumophila RNA prepared from a plasmid construct was used to assess the analytical sensitivity of the assay. The sensitivity of the NASBA assay was 10 molecules of in vitro wild type L. pneumophila RNA and 0.1-1 colony-forming units (CFU) of L. pneumophila. In spiked respiratory specimens, the sensitivity of the NASBA assays was 1-10000 CFU of L. pneumophila serotype 1 depending on the background. After dilution of the nucleic acid extract prior to amplification, 1-10 CFU of L. pneumophila serotype 1 could be detected with both detection methods. Finally, 27 respiratory specimens, well characterized by culture and PCR, collected during a L. pneumophila outbreak, were tested by conventional and real-time NASBAs. All 11 PCR positive samples were positive by conventional NASBA, 9/11 and 10/11 were positive by L. pneumophila real-time NASBA and Legionella spp. real-time NASBA, respectively.     

Development of a Quantitative Real-Time Nucleic Acid Sequence-Based Amplification Assay with an Internal Control Using Molecular Beacon Probes for Selective and Sensitive Detection of Human Rhinovirus Serotypes

Evidence demonstrating that human rhinovirus (HRV) disease is not exclusively limited to the upper airways and may cause lower respiratory complications, together with the frequency of HRV infections and the increasing number of immunocompromised patients underline the need for rapid and accurate diagnosis of HRV infections. In this study, we developed the first quantitative real-time nucleic acid sequence-based amplification assay with an internal control using molecular beacon probes for selective and sensitive detection of human rhinovirus serotypes. We described a simple method to accurately quantify RNA target by computing the time to positivity (TTP) values for HRV RNA. Quantification capacity was assessed by plotting these TTP values against the starting number of target molecules. By using this simple method, we have significantly increased the diagnostic accuracy, precision, and trueness of real-time NASBA assay. Specificity of the method was verified in both in silico and experimental studies. Moreover, for assessment of clinical reactivity of the assay, NASBA has been validated on bronchoalveolar lavage (BAL) specimens. Our quantitative NASBA assay was found to be very specific, accurate, and precise with high repeatability and reproducibility.     

Application of NucliSens Basic Kit for the detection of Mycoplasma pneumoniae in respiratory specimens

A commercially available nucleic acid sequence-based amplification (NASBA) NucliSens Basic Kit (NBK) assay for the detection of Mycoplasma pneumoniae 16S rRNA in respiratory specimens was developed and compared to standard NASBA and PCR assays previously developed in our laboratory. The specificity and sensitivity of the NBK assay was comparable to the specificity and sensitivity of the corresponding standard NASBA assay. The NBK offers standardized reagents for the development of a NASBA assay for the detection of M. pneumoniae in respiratory specimens and is easily adaptable to other amplification targets.     

Rapid detection of human rotavirus using colorimetric nucleic acid sequence-based amplification (NASBA)-enzyme-linked immunosorbent assay in sewage treatment effluent

A colorimetric nucleic acid sequence-based amplification-enzyme-linked immunosorbent assay (NASBA-ELISA) was developed for rapid detection and identification of human rotavirus. Oligonucleotide primers targeting gene 9 encoding a serotype-specific antigen VP7 were selected and used for the amplification of viral RNA by the isothermal NASBA process, resulting in the accumulation of biotinylated RNA amplicons. Amplicons were hybridized with a specific amino-linked oligonucleotide probe covalently immobilized on microtiter plates. The DNA-RNA hybrids were colorimetrically detected by the addition of streptavidin-peroxidase conjugate and tetramethylbenzidine substrate. Using the NASBA-ELISA system, as little as 0.2 PFU (4 x 10(1) PFU ml(-1)) and 15 PFU (3 x 10(3) PFU ml(-1)) of rotavirus were detected within 6 h in spiked MQ water and sewage treatment effluent respectively. No interference was encountered in the amplification and detection of rotavirus in the presence of non-target RNA or DNA. Moreover, the presence of non-target bacteria and virus does not generate any non-specific signal, confirming the specificity of the developed NASBA-ELISA system and its effectiveness in specifically detecting rotavirus. The NASBA-ELISA system offers several advantages in terms of sensitivity, rapidity and simplicity. This technique should be readily adaptable for detection of other RNA viruses in both foods and clinical samples.     

A trap for in situ cultivation of filamentous actinobacteria

The number of pathogens involved in community-acquired pneumonia, with varying susceptibilities to antimicrobials, is numerous constituting an enormous challenge for diagnostic microbiology. Differentiation of infections due to Streptococcus pneumoniae and those due to Mycoplasma pneumoniae, Chlamydophila pneumoniae, or L. pneumophila as well as those due to viruses is essential to allow correct decisions concerning the antibiotics to be administered.

The sensitivity and specificity of real-time simplex and multiplex nucleic acid sequence-based amplification (NASBA), and simplex PCR were compared for the detection of M. pneumoniae, C. pneumoniae and Legionella spp. in respiratory specimens from hospitalized and outpatients with community-acquired pneumonia (CAP).

Two hundred fifty one respiratory specimens were collected from 147 patients with CAP. NASBA was done using the NucliSens Basic Kit (bioMérieux). PCR for M. pneumoniae and C. pneumoniae was done as described earlier [Ieven, M., Ursi, D., Van Bever, H., Quint, W., Niesters, H. G. M., and Goossens, H. 1996. Detection of Mycoplasma pneumoniae by two polymerase chain reactions and role of M. pneumoniae in acute respiratory tract infections in pediatric patients. J. Infect. Dis. 173, 1445–14452.; Ursi, D., Ieven, M., Van Bever, H. P., and Goossens, H. 1998. Construction of an internal control for the detection of Chlamydia pneumoniae by PCR. Mol. Cellul. Probes. 12, 235–238.]. A real-time PCR was developed to detect L. pneumophila whereas a real-time NASBA was designed to detect Legionella spp. All samples with discordant results were re-analysed.

Compared to an expanded gold standard the sensitivities of the different techniques, were 77.8%, 100%, and 100% for detection of M. pneumoniae; and 50%, 100%, and 50% for detection of L. pneumophila by PCR, real-time simplex NASBA, and real-time multiplex NASBA, respectively.

C. pneumoniae was detected in two samples only.

Simplex real-time NASBA proved to be more sensitive than simplex PCR and was also more sensitive than real-time multiplex NASBA, as previously found with spiked clinical specimens. It's practical attractiveness pleads for further optimalisation of the multiplex approach.     

Evaluation of LightCycler as a Platform for Nucleic Acid Sequence-Based Amplification (NASBA) in Real-Time Detection of Enteroviruses

The nucleic acid sequence-based amplification (NASBA) assay has been demonstrated to be more sensitive for detection of enteroviruses (EV) than RT-PCR. Many laboratories, however, do not have a dedicated instrument for the NASBA assay. This study aimed to evaluate the use of the Roche LightCycler as a platform for performing the NASBA assay for detection of EV. A diverse subgenera of EV were used to assess the specificity of the NASBA assay, including coxsackie, echovirus, poliovirus, and other enteroviruses together with related and unrelated viruses, including rhinovirus, respiratory syncytial virus, herpes simplex virus, adenovirus, influenza virus A, and cytomegalovirus. All species of EV tested were successfully detected using NASBA and no cross reactivity with other viruses was observed. Using serial dilutions of EV to assess sensitivity, the NASBA assay was compared to an in-house EV RT-PCR assay. The NASBA assay demonstrated a higher level of sensitivity. Fifty-one clinical samples positive for EV by viral culture were also evaluated. All NASBA results obtained were concordant with viral culture results. This study confirmed that the NASBA assay for the detection of EV could be readily performed on the LightCycler and easily incorporated into the workflow of a diagnostic laboratory equipped with a LightCycler, thereby eliminating the need for additional instrumentation.     

Amplification of RNA by NASBA allows direct detection of viable cells of Ralstonia solanacearum in potato

AIMS: The objective of this study was to develop a Nucleic Acid Sequence Based Amplification (NASBA) assay, targeting 16S rRNA sequences, for direct detection of viable cells of Ralstonia solanacearum, the causal organism of bacterial wilt. The presence of intact 16S rRNA is considered to be a useful indicator for viability, as a rapid degradation of this target molecule is found upon cell death. METHODS AND RESULTS: It was demonstrated by RNase treatment of extracted nucleic acids from R. solanacearum cell suspensions that NASBA exclusively detected RNA and not DNA. The ability of NASBA to assess viability was demonstrated in two sets of experiments. In the first experiment, viable and chlorine-killed cells of R. solanacearum were added to a potato tuber extract and tested in NASBA and PCR. In NASBA, only extracts spiked with viable cells resulted in a specific signal after Northern blot analysis, whereas in PCR, targeting 16S rDNA sequences, both extracts with viable and killed cells resulted in specific signals. In the second experiment, the survival of R. solanacearum on metal strips was studied using NASBA, PCR-amplification and dilution plating on the semiselective medium SMSA. A positive correlation was found between NASBA and dilution plating detecting culturable cells, whereas PCR-amplification resulted in positive reactions also long after cells were dead. The detection level of NASBA for R. solanacearum added to potato tuber extracts was determined at 104 cfu per ml of extract, equivalent to 100 cfu per reaction. With purified RNA a detection level of 104 rRNA molecules was found. This corresponds with less than one bacterial cell, assuming that a metabolically active cell contains ca 105 copies of rRNA. Preliminary experiments demonstrated the potential of NASBA to detect R. solanacearum in naturally infected potato tuber extracts. CONCLUSIONS: NASBA specifically amplifies RNA from viable cells of R. solanacearum even present in complex substrates at a level of 100 cfu per reaction. SIGNIFICANCE AND IMPACT OF THE STUDY: The novel NASBA assay will be particularly valuable for detection of R. solanacearum in ecological studies in which specifically viable cells should be determined.     

Real-Time Nucleic Acid Sequence-Based Amplification Assay for Detection of Hepatitis A Virus

A nucleic acid sequence-based amplification (NASBA) assay in combination with a molecular beacon was developed for the real-time detection and quantification of hepatitis A virus (HAV). A 202-bp, highly conserved 5′ noncoding region of HAV was targeted. The sensitivity of the real-time NASBA assay was tested with 10-fold dilutions of viral RNA, and a detection limit of 1 PFU was obtained. The specificity of the assay was demonstrated by testing with other environmental pathogens and indicator microorganisms, with only HAV positively identified. When combined with immunomagnetic separation, the NASBA assay successfully detected as few as 10 PFU from seeded lake water samples. Due to its isothermal nature, its speed, and its similar sensitivity compared to the real-time RT-PCR assay, this newly reported real-time NASBA method will have broad applications for the rapid detection of HAV in contaminated food or water.     

Real-time nucleic acid sequence-based amplification assay for detection of hepatitis A virus

A nucleic acid sequence-based amplification (NASBA) assay in combination with a molecular beacon was developed for the real-time detection and quantification of hepatitis A virus (HAV). A 202-bp, highly conserved 5' noncoding region of HAV was targeted. The sensitivity of the real-time NASBA assay was tested with 10-fold dilutions of viral RNA, and a detection limit of 1 PFU was obtained. The specificity of the assay was demonstrated by testing with other environmental pathogens and indicator microorganisms, with only HAV positively identified. When combined with immunomagnetic separation, the NASBA assay successfully detected as few as 10 PFU from seeded lake water samples. Due to its isothermal nature, its speed, and its similar sensitivity compared to the real-time RT-PCR assay, this newly reported real-time NASBA method will have broad applications for the rapid detection of HAV in contaminated food or water.     

The use of NASBA for the detection of microbial pathogens in food and environmental samples

The isothermal amplification method nucleic acid sequence-based amplification (NASBA), which amplifies RNA, has been reported as useful for the detection of microbial pathogens in food and environmental samples. Methods have been published for Campylobacter spp., Listeria monocytogenes and Salmonella enterica ser. Enteritidis in various foods and for Cryptosporidium parvum in water. Both 16S rRNA and various mRNAs have been used as target molecules for detection; the latter may have advantages in allowing specific detection of viable cells. Most of the methods to detect pathogens in foods have employed enrichment in nutrient medium prior to NASBA, as this can ensure sensitivity of detection and encourage the detection of only viable target cells. Although a relatively recent method, NASBA has the potential for adoption as a diagnostic tool for environmental pathogens.     

Detection of Vibrio cholerae by real-time nucleic acid sequence-based amplification

A multitarget molecular beacon-based real-time nucleic acid sequence-based amplification (NASBA) assay for the specific detection of Vibrio cholerae has been developed. The genes encoding the cholera toxin (ctxA), the toxin-coregulated pilus (tcpA; colonization factor), the ctxA toxin regulator (toxR), hemolysin (hlyA), and the 60-kDa chaperonin product (groEL) were selected as target sequences for detection. The beacons for the five different genetic targets were evaluated by serial dilution of RNA from V. cholerae cells. RNase treatment of the nucleic acids eliminated all NASBA, whereas DNase treatment had no effect, showing that RNA and not DNA was amplified. The specificity of the assay was investigated by testing several isolates of V. cholerae, other Vibrio species, and Bacillus cereus, Salmonella enterica, and Escherichia coli strains. The toxR, groEL, and hlyA beacons identified all V. cholerae isolates, whereas the ctxA and tcpA beacons identified the O1 toxigenic clinical isolates. The NASBA assay detected V. cholerae at 50 CFU/ml by using the general marker groEL and tcpA that specifically indicates toxigenic strains. A correlation between cell viability and NASBA was demonstrated for the ctxA, toxR, and hlyA targets. RNA isolated from different environmental water samples spiked with V. cholerae was specifically detected by NASBA. These results indicate that NASBA can be used in the rapid detection of V. cholerae from various environmental water samples. This method has a strong potential for detecting toxigenic strains by using the tcpA and ctxA markers. The entire assay including RNA extraction and NASBA was completed within 3 h.     

Fluorescent labeling of NASBA amplified tmRNA molecules for microarray applications

Background  

Here we present a novel promising microbial diagnostic method that combines the sensitivity of Nucleic Acid Sequence Based Amplification (NASBA) with the high information content of microarray technology for the detection of bacterial tmRNA molecules. The NASBA protocol was modified to include aminoallyl-UTP (aaUTP) molecules that were incorporated into nascent RNA during the NASBA reaction. Post-amplification labeling with fluorescent dye was carried out subsequently and tmRNA hybridization signal intensities were measured using microarray technology. Significant optimization of the labeled NASBA protocol was required to maintain the required sensitivity of the reactions.     

Nanodiagnostic Method for Colorimetric Detection of Mycobacterium tuberculosis 16S rRNA

A nanodiagnostic method using nucleic acid sequence-based amplification (NASBA) and gold nanoparticle probes (AuNP probes) was developed for colorimetric detection of Mycobacterium tuberculosis. The primers targeting 16S rRNA were used for the amplification of mycobacterial RNA by the isothermal NASBA process. The amplicons were hybridized with specific gold nanoparticle probes. The RNA–DNA hybrids were colorimetrically detected by the accumulation of gold nanoparticles. Using this method, 10 CFU ml^?1 of M. tuberculosis was detected within less than 1 h. Results obtained from the clinical specimens showed 94.7% and 96% sensitivity and specificity, respectively. No interference was encountered in the amplification and detection of M. tuberculosis in the presence of non-target bacteria, confirming the specificity of the method.     

Nucleic acid sequence-based amplification (NASBA) detection of medically important Candida species.

Nucleic Acid Sequence Based Amplification (iNASBA), an isothermal amplification technique for nucleic acids, was evaluated for the identification of medically important Candida species using primers selected from 18S rRNA sequences conserved in fungi. An RNA fragment of 257 nucleotides was amplified for Candida albicans. Nineteen different fungi were tested for rRNA amplification with the NASBA. All were positive when analyzed on agarose gel, whereas human RNA was negative. For the identification of Candida species, NASBA amplification products were analyzed in an enzyme bead-based detection format, using species-specific biotinylated probes and a generic Candida HRPO probe or a membrane-based system using biotinylated probes and avidin-HPRO. Discrimination of the major human pathogenic Candida spp. was based on a panel of biotinylated probes for C. krusei, C. tropicalis, C. albicans, C. glabrata, and C. lusitaniae. Using rRNA dilutions obtained from pure cultures of C. albicans, the combination of NASBA and the enzymatic bead-based detection yielded a sensitivity equivalent to 0.01 CFU. In a model system using 1 ml of artificially contaminated blood as few as 1-10 CFU of C. albicans could be detected. Testing of 68 clinical blood samples from patients suspected of candidemia showed that eight samples were positive for C. albicans and one for C. glabrata. Testing of 13 clinical plasma samples from patients suspected of fungemia identified the presence of C. albicans in two specimens. The whole procedure of sample preparation, amplification and identification by hybridization can be performed in 1 day. This speed and the observed sensitivity of the assay make the NASBA a good alternative to PCR for the detection of candidemia.     

NASBA荧光分子信标技术定量检测丙型肝炎病毒

建立NASBA荧光分子信标探针检测技术,并对国家HCV标准品、人工构建HCVRNA野生株及HCV抗体阳性不同人群进行检测。实验结果:该方法检测HCV的灵敏度为103拷贝ml血清,阴性参比品的符合率为100%;检测的线性范围为103拷贝～109拷贝ml血清;精密性(CV值)小于6%,在HCV抗体阳性人群中HCVRNA的检出率在45%～65%之间。结论:该方法在HCVRNA临床定量检测中具有良好的灵敏度、特异性、重复性与实用性。     

Detection of Campylobacter jejuni added to foods by using a combined selective enrichment and nucleic acid sequence-based amplification (NASBA).

An assay to detect Campylobacter jejuni in foods that uses a short selective enrichment culture, a simple and rapid isolation procedure, NASBA amplification of RNA, and a nonradioactive in solution hybridization was studied. The presence of high numbers of indigenous flora affected the sensitivity of the assay. However, detection of C. jejuni was possible up to a ratio of indigenous flora to C. jejuni of 10,000:1. Interference by food components was eliminated by centrifugation following the enrichment step. Fourteen food samples artificially inoculated with C. jejuni (1 to 1,000 CFU/10 g) were analyzed with the NASBA assay and the conventional culture method with Campylobacter charcoal differential agar (CCDA). A few false-negative results were obtained by both NASBA (1.42%) and CCDA (2.86%) isolation. Yet the use of enrichment culture and NASBA shortened the analysis time from 6 days to 26 h. The relative simplicity and rapidity of the NASBA assay make it an attractive alternative for detection of C. jejuni in food samples.