Application of Advanced Molecular Techniques in Applied Environmental Microbiology

Iker, Brandon Charles

January 2013

Recent advancements in molecular biology such as next generation sequencing and more sensitive and rapid molecular detection methods like qPCR, have historically been developed for clinical applications in human genetics and for health care diagnostic purposes. The high demand for faster and more accurate molecular assays in the health care field has driven rapid development of inexpensive molecular techniques that when applied to the science of environmental microbiology, provides an unprecedented level of understanding of the microbial world around us. The goal of this dissertation is to begin to apply more advanced molecular technologies to problems in applied environmental microbiology. Appendix A is a brief literature review of next generation sequencing technologies for applications in environmental microbiology. Appendix B focuses on the development of a more robust virus nucleic extraction kit for the detection of viral genomes from environmental samples found to contain high concentrations of qPCR inhibitors, such as humic acids or heavy metals. Appendix C summarizes one of the largest virus surveys done in the US, using state of the art qPCR technologies in both wastewater influent and effluent from two wastewater treatment plants in the Southwest. Data suggests that traditional virus indicators may not be a viable tool to evaluate fecally impacted source water or virus removal during water treatment. The third study summarized in Appendix D, provides one of the first insights into the microbial ecology of biofilms utilized as biological treatment media using Roche 454 amplicon sequencing of the 16S rRNA gene.

nucleic acid extraction

pathogens

P.O.U.

virus

water filtration

Soil, Water & Environmental Science

next generation sequencing

From Tissue to Mutations : Genetic Profiling of Colorectal Cancer

Mathot, Lucy

January 2014

Comprehensive characterisation of the mutational landscapes of solid tumours is a multistep process involving the collection of suitable samples, the extraction of nucleic acids and the preparation of these materials for mutational analyses. In this thesis, I aimed to develop a streamlined process for the analysis of colorectal cancer (CRC) patient samples in order to identify novel mutations that hallmark the development of advanced disease. Papers I and II outline a technique for serial extraction of nucleic acids from frozen tissue that we developed and subsequently implemented on a robotic platform to enable high-throughput processing. The extracted nucleic acids were validated in downstream processes relevant for genetic analyses, including traditional Sanger and next generation sequencing  techniques. In Paper III, we developed a genotyping method based on multiplex ligation-dependent genome amplification. The method was designed such that InDel polymorphisms of between 30 and 70 % prevalence in a European population were selected and amplified in a multiplex PCR assay. DNA from 24 patient-matched colorectal tumour and normal tissues was genotyped and paired with a high match probability. In Paper IV, we performed targeted resequencing of 107 primary CRCs, of which approximately half developed metastatic disease or had distant metastases at the time of diagnosis. We chose to analyse 676 genes based on their involvement in key signalling pathways in CRC. We found an enrichment of mutations in the Eph receptor tyrosine kinase gene family in metastatic patients, indicating a potential role for these genes in CRC metastasis. This thesis outlines a series of procedures that can be employed in a high-throughput setting for the analysis of solid tumours. We applied these methods to the analysis of colorectal tumours and propose a link between novel somatic mutations and metastatic disease.

Nucleic acid extraction

genotyping

targeted sequencing

mutation analysis

colorectal cancer

metastatic disease

<b>TOWARDS QUANTITATIVE MOLECULAR ISOTHERMAL AMPLIFICATION FOR POINT-OF-CARE HIV VIRAL LOAD MONITORING</b>

Emeka Nwanochie (18320661)

22 April 2024

<p dir="ltr">Since the beginning of the HIV/AIDS epidemic, 85.6 million people worldwide have become infected with HIV; more than half of whom have died from AIDS-related complications.[1] Sustained viral suppression below the clinically relevant threshold (1000 copies per mL) with highly active antiretroviral therapy (HAART) has proven effective at managing and prolonging the life expectancy of people living with HIV (PLHIV). However, in 2022, 11.3 million PLHIV had still not achieved viral suppression and may become susceptible to both HIV transmission and a variety of opportunistic infections. Of particular importance is the complex issue of patient non-compliance in global HIV management due to social, economic, behavioral, and healthcare access barriers, potentially disconnecting many PLHIV from the HIV care continuum. Therefore, to boost patient engagement in clinical care and to improve overall patient outcomes, new approaches to viral load monitoring practices need to be developed to increase access, particularly in regions of high HIV prevalence.</p><p dir="ltr">Nucleic acid amplification tests (NAATs) have emerged as potent tools for monitoring viral load, with reverse transcription quantitative polymerase chain reaction (RT-qPCR) being recognized as the benchmark due to its sensitivity and ability for real-time quantification enabled by fluorescence signal emission. Nevertheless, RT-qPCR is burdened by drawbacks including extended processing times, high operational costs, and the requirement for specialized laboratory facilities. In this study, we propose a novel method for HIV-1 viral load monitoring by integrating reverse-transcriptase loop-mediated isothermal amplification (RT-LAMP) with real-time particle diffusometry (PD). This approach allows for the continuous monitoring of changes in the diffusion of 400 nm fluorescent particles during RT-LAMP amplification, targeting the <i>p24</i> gene region of HIV-1 RNA. This enables the real-time detection of amplification curves, achieving a detection sensitivity in water samples as low as 25 virus particles per μL within a short duration of 30 minutes. Additionally, to address challenges related to amplification inhibition in complex human specimens, we developed a power-free sample processing system specifically designed for extracting HIV-1 RNA from both whole blood and plasma.Top of FormBottom of FormThis system modifies a commercially available spin-column protocol by integrating a syringe device and handheld bulb dryer, thus eliminating the requirement for a centrifuge. The adaptation allows for the completion of the entire extraction procedure, encompassing viral lysis, RNA capture, washing, and elution of purified HIV-1 RNA, within a timeframe of less than 16 minutes. Subsequent analyses, including RT-LAMP and RT-qPCR, demonstrate a limit of detection of 100 copies per μL and an average RNA recovery of 32% (for blood) and 70% (for plasma) in the elution fraction. Further investigations emphasize the significant presence of purified RNA in the spin column volume (termed as dead volume), and the cumulative recovered RNA copies align with those obtained using the gold standard centrifugation extraction method. Ultimately, we incorporated the real-time quantitative PD-RT-LAMP assay onto a field-compatible handheld portable platform suitable for field use, featuring built-in quality control measures. This platform enables sample-to-answer viral load testing near the point of care (POC). Subsequently, we undertook essential preparatory steps, such as reagent drying to obviate the need for cold storage, initial device calibration, and hands-on training of laboratory personnel regarding device operation, to validate device performance within a cohort of individuals living with HIV (PLHIV). These innovations facilitate quick and comprehensive viral load determination, offering promise for enhanced HIV management and patient care</p>

Biomedical instrumentation

Medical devices

particle diffusometry

HIV

viral load monitoring

quantitative

nucleic acid amplification

whole blood

nucleic acid extraction

internal control