Project description:The detection of pathogens is critical for clinical diagnosis and public health surveillance. Detection is usually done with nucleic acid-based tests (NATs) and rapid antigen tests (e.g., lateral flow assays [LFAs]). Although NATs are more sensitive and specific, their use is often limited in resource-poor settings due to specialized requirements. To address this limitation, we developed a rapid DNA-RNA Hybrid Capture immunoassay (HC) that specifically detects RNA from pathogens. This assay utilizes a unique monoclonal antibody, S9.6, which binds DNA-RNA hybrids. Biotinylated single-stranded DNA probes are hybridized to target RNAs, followed by hybrid capture on streptavidin and detection with S9.6. The HC-ELISA assay can detect as few as 104 RNA molecules that are 2.2 kb in length. We also adapted this assay into a LFA format, where captured Bacillus anthracis rpoB RNA of 3.5 kb length was detectable from a bacterial load equivalent to 107 CFU per 100 mg of mouse tissue using either HC-ELISA or HC-LFA. Importantly, we also demonstrated the versatility of HC by detecting other pathogens, including SARS-CoV-2 and Toxoplasma gondii, showing its potential for broad pathogen detection. Notably, HC does not require amplification of the target nucleic acid and utilizes economical formats like ELISA and LFA, making it suitable for use in sentinel labs for pathogen detection or as a molecular tool in basic research laboratories. Our study highlights the potential of HC as a sensitive and versatile method for RNA-based pathogen detection.

Project description:As plants are confined to the place where they grow, they have to develop a broad range of defence responses to cope with pathogenic infections. The oxidative burst, a rapid, transient, production of huge amounts of reactive oxygen species (ROS), is one of the earliest observable aspects of a plant's defence strategy. First this Review describes the chemistry of ROS (superoxide radical, hydrogen peroxide and hydroxyl radical). Secondly, the role of ROS in defence responses is demonstrated, and some important issues are considered, such as: (1) which of the ROS is a major building element of the oxidative burst; (2) the spatial and temporal regulation of the oxidative burst; and (3) differences in the plant's responses to biotic and abiotic elicitation. Thirdly, the relationships between the oxidative burst and other plant defence responses are indicated. These include: (1) an oxygen consumption, (2) the production of phytoalexins, (3) systemic acquired resistance, (4) immobilization of plant cell wall proteins, (5) changes in membrane permeability and ion fluxes and (6) a putative role in hypersensitive cell death. Wherever possible, the comparisons with models applicable to animal systems are presented. Finally, the question of the origin of ROS in the oxidative burst is considered, and two major hypotheses, (1) the action of NADPH oxidase system analogous to that of animal phagocytes, and (2) the pH-dependent generation of hydrogen peroxide by a cell wall peroxidase, are presented. On the basis of this material, a third 'unifying' hypothesis is presented, where transient changes in the pH of the cell wall compartment are indicated as a core phenomenon in evoking ROS production. Additionally, a germin/oxalate oxidase system which generates H2O2 in response to pathogenic infection is also described.

Project description:Accurate diagnosis of Alzheimer’s disease (AD) in its earliest stage can prevent the disease and delay the onset of symptoms by maintaining a healthy lifestyle and controlling modifiable risk factors. Therefore, more sensitive, relatively inexpensive, non-invasive, and simple screening tools are required for the early diagnosis and progression monitoring of AD. Here, we designed a self assembled nanoparticle-mediated amplified fluorogenic immunoassay (SNAFIA) consisting of magnetic and fluorophore-loaded polymeric nanoparticles. Multiple simultaneous captures and magnetic separation of biomarkers and target-specific fluorophore emission induced a one-tomulti signal, resulting in a low detection limit (236 aM), good reliability (R2 = 0.991), and wide analytical range (0.320–1000 fM) for APOE and CAP1 biomarkers in human serum and tear fluid. More importantly, SNAFIA successfully differentiated AD patients from healthy controls with 90% sensitivity and 100% specificity in less than 1 h in 39 clinical tear samples. As an easily accessible diagnostic tool with fast and accurate results, SNAFIA can help diagnose AD early to aid in long-term care planning, increase the efficiency of clinical trials, and dramatically accelerate therapeutic development.

Project description:Background: In industrialised countries diphtheria is a rare but still life-threatening disease with a recent increase in cases due to migration and zoonotic aspects. Due to the rarity of the disease, laboratory diagnosis of diphtheria is often carried out in central reference laboratories and involves the use of sophisticated equipment and specially trained personnel. The result of the diphtheria agent detection can usually be obtained after 5-6 days or more. Authors suggest a Lateral Flow Immunoassay (LFIA)-based laboratory algorithm for the diagnosis of diphtheria, which may render less time in issuing a result and could promote the testing be performed in laboratories closer to the patient. Methods: LFIA for diphtheria toxin (DT) detection was designed using a pair of monoclonal antibodies to receptor-binding subunit B of the DT, and validated with 322 corynebacterial cultures as well as 360 simulated diphtheria specimens. Simulated diphtheria specimens were obtained by spiking of human pharyngeal samples with test strains of corynebacteria. The simulated specimens were plated on selective tellurite agar and after 18-24 hours of incubation, grey/black colonies characteristic of the diphtheria corynebacteria were examined for the DT using LFIA. Results: The diagnostic sensitivity of the LFIA for DT detection on bacterial cultures was 99.35%, and the specificity was 100%. Also, the LFIA was positive for all pharyngeal samples with toxigenic strains and negative for all samples with non-toxigenic strains. For setting LFIA, a 6-hour culture on Elek broth was used; thus, under routine conditions, the causative agent of diphtheria could be detected within two working days after plating of the clinical specimen on the tellurite medium of primary inoculation. Conclusions: The availability of such a simple and reliable methodology will speed up and increase the accuracy of diphtheria diagnosis globally.

Project description:Helicobacter pylori colonizes half of the world's population, and infection can lead to ulcers, gastric cancer, and mucosa-associated lymphoid tissue (MALT) lymphoma. Serology is the only test applicable for large-scale, population-based screening, but current tests are hampered by a lack of sensitivity and/or specificity. Also, no serologic test allows the differentiation of type I and type II strains, which is important for predicting the clinical outcome. H. pylori virulence factors have been associated with disease, but direct assessment of virulence factors requires invasive methods to obtain gastric biopsy specimens. Our work aimed at the development of a highly sensitive and specific, noninvasive serologic test to detect immune responses to important H. pylori virulence factors. This line immunoassay system (recomLine) is based on recombinant proteins. For this assay, six highly immunogenic virulence factors (CagA, VacA, GroEL, gGT, HcpC, and UreA) were expressed in Escherichia coli, purified, and immobilized to nitrocellulose membranes to detect serological immune responses in patient's sera. For the validation of the line assay, a cohort of 500 patients was screened, of which 290 (58.0%) were H. pylori negative and 210 (42.0%) were positive by histology. The assay showed sensitivity and specificity of 97.6% and 96.2%, respectively, compared to histology. In direct comparison to lysate blotting and enzyme-linked immunosorbent assay (ELISA), the recomLine assay had increased discriminatory power. For the assessment of individual risk for gastrointestinal disease, the test must be validated in a larger and defined patient cohort. Taking the data together, the recomLine assay provides a valuable tool for the diagnosis of H. pylori infection.

Project description:Accurate diagnosis of Alzheimer's disease (AD) in its earliest stage can prevent the disease and delay the symptoms. Therefore, more sensitive, non-invasive, and simple screening tools are required for the early diagnosis and monitoring of AD. Here, we design a self-assembled nanoparticle-mediated amplified fluorogenic immunoassay (SNAFIA) consisting of magnetic and fluorophore-loaded polymeric nanoparticles. Using a discovery cohort of 21 subjects, proteomic analysis identifies adenylyl cyclase-associated protein 1 (CAP1) as a potential tear biomarker. The SNAFIA demonstrates a low detection limit (236 aM), good reliability (R2 = 0.991), and a wide analytical range (0.320-1000 fM) for CAP1 in tear fluid. Crucially, in the verification phase with 39 subjects, SNAFIA discriminates AD patients from healthy controls with 90% sensitivity and 100% specificity in under an hour. Utilizing tear fluid as a liquid biopsy, SNAFIA could potentially aid in long-term care planning, improve clinical trial efficiency, and accelerate therapeutic development for AD.

Project description:A sensitive and specific system for detection of amplified Chlamydia trachomatis DNA from cervical specimens by fluorometric quantitation in an enzyme immunoassay (EIA) format (polymerase chain reaction [PCR]-EIA) is described. The primers selected for PCR-amplified DNA were from the 15 serovars of C. trachomatis and two strains of Chlamydia pneumoniae (TWAR). One strain of Chlamydia psittaci (Borg) was not amplified. One hundred four previously cultured cervical specimens were evaluated. Forty-six culture-positive specimens containing from 1+ to 4+ inclusion bodies were all positive by PCR-EIA. Of 58 culture-negative specimens, 2 were repeatedly positive and were nonreactive with control probes. This assay system represents a sensitive and specific combination of technologies for the quantitative detection of C. trachomatis DNA directly from a body fluid.

Project description:BackgroundThere is an urgent need for rapid, sensitive, and affordable diagnostics for microbial infections at the point-of-care. Although a number of innovative systems have been reported that transform mobile phones into potential diagnostic tools, the translational challenge to clinical diagnostics remains a significant hurdle to overcome.MethodsA smartphone-based real-time loop-mediated isothermal amplification (smaRT-LAMP) system was developed for pathogen ID in urinary sepsis patients. The free, custom-built mobile phone app allows the phone to serve as a stand-alone device for quantitative diagnostics, allowing the determination of genome copy-number of bacterial pathogens in real time.FindingsA head-to-head comparative bacterial analysis of urine from sepsis patients revealed that the performance of smaRT-LAMP matched that of clinical diagnostics at the admitting hospital in a fraction of the time (~1?h vs. 18-28?h). Among patients with bacteremic complications of their urinary sepsis, pathogen ID from the urine matched that from the blood - potentially allowing pathogen diagnosis shortly after hospital admission. Additionally, smaRT-LAMP did not exhibit false positives in sepsis patients with clinically negative urine cultures.InterpretationThe smaRT-LAMP system is effective against diverse Gram-negative and -positive pathogens and biological specimens, costs less than $100 US to fabricate (in addition to the smartphone), and is configurable for the simultaneous detection of multiple pathogens. SmaRT-LAMP thus offers the potential to deliver rapid diagnosis and treatment of urinary tract infections and urinary sepsis with a simple test that can be performed at low cost at the point-of-care. FUND: National Institutes of Health, Chan-Zuckerberg Biohub, Bill and Melinda Gates Foundation.

Project description:In the vineyard, symptoms of the grapevine trunk disease Botryosphaeria dieback do not appear until 1 or 2 years after the causal fungus Neofusicoccum parvum establishes a necrotic canker in the permanent woody structure of the vine. There are preventative management practices, but growers tend to wait until symptoms are widespread, at which point prevention has limited efficacy. Toward development of an early detection tool, we examined the leaves of inoculated vs. non-inoculated plants for differential gene expression via RNASeq. Stems were examined to monitor spread of the infection, and its spatial and temporal relationship to anatomical changes via light microscopy and high resolution computed tomography (HRCT). The early stage of infection occurred prior to 2 months post-inoculation (MPI), at which point spread of the pathogen beyond the inoculation site was greatest. This incubation period was also characterized by the largest stem lesions, the highest levels of fungal colonization and xylem vessels fully-occluded by gels, and the lowest starch content of xylem fibers and rays. Prior to 2 MPI, RNASeq and validative qPCR analysis identified eight candidate markers, which are transcriptionally activated by infection, but not by wounding alone. Our best marker genes, a dehydrin, a BURP domain containing protein and an abscissic acid-induced wheat plasma membrane polypeptide 19 (AWPM-19), identified the pathogenâ??s presence with high specificity. Screening of genome-wide expression data revealed that this signature is not affected by many abiotic and biotic stresses. Asymptomatic leaf mRNA profiles of Neofusicoccum parvum infected wounded plants (IW) and non-infected wounded plants (NIW) at two different time points post inoculation (0 MPI, 0.5-1.5 MPI) were generated by deep sequencing in biological triplicates using Illumina HiSeq2500 technology.

Project description:In the vineyard, symptoms of the grapevine trunk disease Botryosphaeria dieback do not appear until 1 or 2 years after the causal fungus Neofusicoccum parvum establishes a necrotic canker in the permanent woody structure of the vine. There are preventative management practices, but growers tend to wait until symptoms are widespread, at which point prevention has limited efficacy. Toward development of an early detection tool, we examined the leaves of inoculated vs. non-inoculated plants for differential gene expression via RNASeq. Stems were examined to monitor spread of the infection, and its spatial and temporal relationship to anatomical changes via light microscopy and high resolution computed tomography (HRCT). The early stage of infection occurred prior to 2 months post-inoculation (MPI), at which point spread of the pathogen beyond the inoculation site was greatest. This incubation period was also characterized by the largest stem lesions, the highest levels of fungal colonization and xylem vessels fully-occluded by gels, and the lowest starch content of xylem fibers and rays. Prior to 2 MPI, RNASeq and validative qPCR analysis identified eight candidate markers, which are transcriptionally activated by infection, but not by wounding alone. Our best marker genes, a dehydrin, a BURP domain containing protein and an abscissic acid-induced wheat plasma membrane polypeptide 19 (AWPM-19), identified the pathogen’s presence with high specificity. Screening of genome-wide expression data revealed that this signature is not affected by many abiotic and biotic stresses.