Development of multiplex rt-PCR assays for rapid detection and subtyping of influenza type A viruses from clinical specimens

We developed multiplex RT-PCR assays that can detect and identify 12 hemagglutinin (H1-H12) and 9 neuraminidase (N1-N9) subtypes that are commonly isolated from avian, swine, and human influenza A viruses. RT-PCR products with unique sizes characteristic of each subtype were amplified by multiplex RT-PCRs, and sequence analysis of each amplicon was demonstrated to be specific for each subtype with 24 reference viruses. The specificity was demonstrated further with DNA or cDNA templates from 7 viruses, 5 bacteria, and 50 influenza A virus negative specimens. Furthermore, the assays could detect and subtype up to 105 dilution of each of the reference viruses that had an original infectivity titer of 106 EID50/ml. Of 188 virus isolates, the multiplex RT-PCR results agreed completely with individual RT-PCR subtyping results and with results obtained from virus isolations. Furthermore, the multiplex RT-PCR methods efficiently detected mixed infections with at least two different subtypes of influenza viruses in one host. Therefore, these methods could facilitate rapid and accurate subtyping of influenza A viruses directly from field specimens.     

Negative staining in the detection of viruses in clinical specimens

Viruses have unique morphology and are therefore good candidates for negative staining. Negative staining with phosphotungstic acid (PTA) or uranyl acetate has facilitated the detection of many viruses in clinical specimens. Enhancement procedures have included the use of centrifugation and agar diffusion for concentrating virus particles, the use of solid phase capture reagents to trap virus particles and the use of secondary antibodies and electron dense markers to help visualize them. Techniques currently in use and employing negative staining include direct EM, immune electron microscopy (IEM), solid phase immune electron microscopy (SPIEM), colloidal gold-labeled protein A (PAG), solid phase IEM employing a second decorator antibody (SPIEMDAT), and solid phase IEM using colloided gold-labeled secondary antibodies (SPEIMDAGT). IEM methods assist with the detection of small viruses or viruses present in low numbers while PAG offers increased sensitivity over direct EM and IEM. In our experience the serum-in-agar (SIA) method is the most sensitive of the PAG IEM techniques for detection of rotavirus particles in clinical specimens. SPIEMDAT enhances the detection of small viruses which are often missed by other techniques due to background staining in specimens. SPEIMDAGT employing colloidal gold-labeled secondary antibody has increased sensitivity and offers the advantage of detecting viral antigen when whole virus particles are not visible. IEM techniques have recently been used for typing viruses using either monospecific antisera or monoclonal antibodies and colloidal gold-labeled secondary antibody.     

Electron microscopy of twoPelargonium viruses

Summary Samples ofPelargonium zonale with different virus symptoms were collected from several gardens in Madrid. Inoculation to test plants and electron microscopy of the samples were made.2 viruses were isolate from the samples; by symptomatology, size of the virus particles, and distribution of the virions in the host cells, one of them (P₁) was identified withPelargonium leaf curl and the other (P₂) seems to be a previously undescribed virus. The virus P₂ forms crystalline inclusions composed of virus particles in the vacuoles of the infected cells.     

An extremely rapid and simple DNA-release method for detection of M. tuberculosis from clinical specimens

A single-step, 5-min lysis method was investigated as a rapid technique to extract genomic DNA from mycobacteria for PCR detection of M. tuberculosis directly from clinical specimens. Of 67 smear-positive clinical specimens, 64 (95.5%) were positive by PCR after this rapid extraction method.     

Real-time multiplex PCR for rapid detection of enteroviruses, adenoviruses and hepatitis A virus in clinical specimens

Real-time multiplex polymerase chain reaction (PCR) with internal positive control (IPC) was developed for simultaneous detection of adenoviruses (AV), enteroviruses (EV) and hepatitis A virus (HAV). Primes and probes labeled with different fluorophores (FAM, R6G, ROX, and Cy5) and able to detect up to four viral RNAs (DNAs) with high specificity in a single tube in real-time PCR were designed. Sensitivity and specificity of the method was estimated using cultural strains of 8 serotypes of EV, 5 serotypes of AV and 2 clinical specimens containing HAV. Sensitivity of the method for detection of polioviruses types 1, 2, and 3 (Sabin vaccine strains) was 0.5--1 TCID50 per reaction mixture. Thirty clinical specimens were analyzed by the multiplex PCR with and without IPC, and by mono-specific PCR. Comparison of these methods with cultural one revealed results agreement in 86.7% in case of multiplex PCR with IPC and in 100% in case of multiplex PCR without IPC and mono-specific PCR. This method can be used for rapid diagnostics of enteric viral infections as well as for determination of viral contamination level of water. As intermediate results of the study the methods for quantitative assessment of HAV, AV, and EV nucleic acids were developed which are convenient tools for the control of antiviral therapy effectiveness.     

Electron microscopy: essentials for viral structure, morphogenesis and rapid diagnosis

Electron microscopy(EM) should be used in the front line for detection of agents in emergencies and bioterrorism,on accounts of its speed and accuracy.However,the number of EM diagnostic laboratories has decreased considerably and an increasing number of people encounter difficulties with EM results.Therefore,the research on viral structure and morphology has become important in EM diagnostic practice.EM has several technological advantages,and should be a fundamental tool in clinical diagnosis of viruses,particularly when agents are unknown or unsuspected.In this article,we review the historical contribution of EM to virology,and its use in virus differentiation,localization of specific virus antigens,virus-cell interaction,and viral morphogenesis.It is essential that EM investigations are based on clinical and comprehensive pathogenesis data from light or confocal microscopy.Furthermore,avoidance of artifacts or false results is necessary to exploit fully the advantages while minimizing its limitations.     

A simple medium for isolation and identification of Candida albicans directly from clinical specimens

A simple and specific medium consisting of chitosan, trypticase, Tween-80 and agar is devised to isolate the organisms directly from the clinical specimens and to produce germ tubes and chlamydospores for rapid differentiation and identification of Candida albicans from other closely related Candida species. By manipulating the incubating conditions, the specific phase of the organism can be produced in liquid or on solid medium at different time intervals to study the physiology of the organism.Many methods and media have been proposed in the past for identification of Candida albicans and to differentiate this from the closely related species of Candida (5–8, 15). Taschdjian, Burchall&Kozinn (15) showed that C. albicans produces germ tube within an hour or two when it is grown in human or animal serum or serum substitutes. The specificity of this germ tube test was later confirmed by various workers by using different media (3–5). The distinctive feature that differentiates C. albicans from other species is the production of chlamydospores (14). However, in all these studies three types of media were required to isolate the organisms from clinical specimens and to produce germ tubes and chlamydospores for identification. Recently studies have shown that a single medium can be employed to produce both structural components of the organism from the primary isolation medium but the preparation of the medium is more exhaustive (1) and time consuming (13) than the medium to be described here. The present investigation was therefore undertaken to develop a simple and specific medium to isolate the organism directly from the clinical specimens and to produce various morphological phases of Candida albicans to differentiate from other closely related Candida species for clinical diagnosis and to provide a medium to study the physiology and metabolism of the organism under in vitro conditions.Supported in part by Grant CA 20917, National Cancer Institute, National Institutes of Health and ALSAC.     

A rapid method for detection of Y-chromosomal DNA from dried blood specimens by the polymerase chain reaction

Summary The alphoid satellite family is the only repetitive DNA family showing chromosome specificity. We have developed a simple, rapid, and reliable test for sex diagnosis based on detection of these sequences in undigested genomic DNA using the polymerase chain reaction. In our test, dried blood specimens were the source of DNA. When female DNA was used as a template for the reaction, only the expected 130-bp X-chromosome-specific fragment was detected, while with male DNA both the expected 170-bp Y-chromosome-specific and X-chromosome-specific fragments were detected. The Y-chromosome-specific fragment was further characterized by restriction enzyme analysis. The Y fragment was detectable when DNA obtained from an equivalent of 10 l of spotted blood was used in the reaction, whereas detection of the X fragment was possible with DNA from an equivalent of 5 l of blood. Our test may find various applications in newborn screening and in forensic science.