Genomic Tools Reveal Changing Plasmodium falciparum Populations

Daniels, Rachel Fath

25 September 2013

A new era of malaria eradication programs relies on increased knowledge of the parasite through sequencing of the Plasmodium genome. Programs call for re-orientation at specific epidemiological markers as regions move from control towards pre- and total elimination. However, relatively little is known about the effects of intervention strategies on the parasite population or if the epidemiological cues correspond to effects on the parasite population. We hypothesized that genomic tools could be used to track population changes in Plasmodium falciparum to detect significant shifts as eradication programs apply interventions. Making use of new whole-genome sequencing data as well as GWAS and other studies, we used SNPs as biological markers for regions associated with drug resistance as well as a set of neutral SNPs to identify individual parasites. By utilizing tools developed as proxy for full genomic sequencing of the human pathogen Plasmodium falciparum, we characterized and tracked parasite populations to test for changes over time and between populations. When applied to markers under selection - those associated with reduced antimalarial drug sensitivity - we were able to track migration of resistance-associated mutations in the population and identify new mutations with potential implications for resistance. Using a population genetic analysis toolbox to study changes in neutral allele frequencies in samples from the field, we found significant population changes over time that included restricted effective population size, reduced complexity of infections, and evidence for both clonal and epidemic propagation of parasites.

Biology

Parasitology

cerebral malaria

drug resistance

high resolution melting

molecular barcode

plasmodium falciparum

population genetics

Multiplexed cell-based assays to profile GPCR activities and cellular signalling

Galinski, Sabrina

25 February 2016

No description available.

570

G protein-coupled receptor

GPCR

cell-based

molecular barcode

multiplexed assay

receptor activation

downstream signalling

Biologie (PPN619462639)

Analysing Non-Desired Output Data from High Throughput Sequencers for the Identification of the Source of Contamination / Analys av oönskade utdata från högkapacitetssekvenserare för identifikation av kontamineringskällor

Martinez Maldonado, Mayra Guadalupe

January 2022

High-throughput Sequencing (HTS)-tekniker fortsätter att utvecklas snabbt, vilket ökar genomströmningen och minskar sannolikheten för fel. MGI Tech Co., Ltd. (MGI) är ett ledande HTS-varumärke som använder DNBSEQ-teknologi och finns i Center for Translational Microbiome (CTMR). MGI:s sequencers har en hög känslighet och det är viktigt att följa protokollen när proverna hanteras för att undvika introduktion av kontaminering. Detta projekt kommer att utforska tidigare genererade data vid CTMR för att fastställa hur och var i sekvenseringsprocessen kontaminering har introducerats. Data delas in i två huvudkategorier: primärdata, eller verkliga data (RD), och sekundära data, vidare uppdelad i Never Used Barcodes (NUB) och Non-Sequenced (NS). RD:n är sann mot provet, medan NUB och NS anses vara hämtade från bakgrundsbrus. RD, NUB och NS var föremål för taxonomiska analyser, på släkt- och artnivå, och streckkodsanalyser med hjälp av RStudio-gränssnittet för att identifiera och kontrastera de vanligaste i varje kategori. Dessutom var RD också föremål för dekontamineringsanalys på två databaser, VaMyGyn och KOLBIBAKT. Dekontaminering används för att identifiera förorenande arter i ett samhälle. Efter analysen fanns det inga starka bevis som tydde på laboratoriekontamination eller kontaminerade reagenser. Några av dessa NUB delade subsekvenser med RD barcodes, där antal reads för varje par var korrelerade mellan prover. Det kan vara en indikation på att RD barcoded med sekvenseringsfel blir inkorrekt tolkade som NUB. En djupare analys skulle krävas för att bekräfta det.CTMR är numera medveten om att kontaminering från laboratoriet, reagenser eller manipulation inte är orsaken till hämtning av bakgrundsljud. / High-throughput sequencing (HTS) technologies keep developing rapidly, increasing throughput and lowering probabilities of errors. MGI Tech Co., Ltd. (MGI) is a leading HTS brand that uses DNBSEQ technology and is present in the Centre for Translational Microbiome (CTMR). MGI’s sequencers have a high sensitivity and it is critical to follow the protocols when the samples are being handled to avoid introduction of contamination. This project will explore the previously generated data at CTMR to determine how and where in the sequencing process contamination has been introduced. Data is divided into two main categories: the primary data, or real data (RD), and secondary data, further divided into Never Used Barcodes (NUB) and Non-Sequenced (NS). The RD is true to the sample, while NUB and NS are considered background noise retrieved. The RD, NUB, and NS were subject to taxonomic analyses, at genus and species level, and barcode analyses using the RStudio interface to identify and contrast the most frequent in each category. Moreover, RD was also subject to decontam analysis on two databases, VaMyGyn and KOLBIBAKT. Decontam is used for the identification of contaminant species in a community. After the analysis, there was no strong evidence suggesting lab contamination or contaminated reagents. Some of the barcodes from NUB shared substrings with RD barcodes for which the amount of reads were correlated across samples. This may indicate that RD barcodes with sequencing errors are falsely identified as NUB, however, more analyses are needed to verify this. CTMR is now aware that contamination from the lab, reagents, or manipulation are not the causes for the background noise retrieval.

high-throughput sequencing

metagenomics

MGI

contamination

molecular barcode

högkapacitetssekvensering

metagenomik

MGI

kontaminering

DNA-streckkod