Development of a Confirmatory PCR Assay to Detect Onchocerca volvulus in Pools of Vector Black Flies

Talsma, Alex Jeanne

01 January 2013

Onchocerciasis, or river blindness, has historically represented one of the significant neglected tropical diseases on the planet in terms of socio-economic impact. The discovery that ivermectin was a safe and effective treatment for onchocerciasis, together with the decision of the manufacturer to donate the drug for the treatment of this disease became the basis for several large international programs to control and eventually eliminate the infection. These programs have managed to virtually eliminate transmission of the parasite causing Onchocerca volvulus from many foci in Africa and the Americas. Verifying that transmission has been halted requires sensitive and specific assays to detect the presence of the parasite. The gold standard to accomplish this has been to employ a PCR assay targeting a specific repeated sequence family encoded in the genome of O. volvulus to screen for the presence of the parasite in pools of vector black flies. While this assay is highly sensitive, obtaining the high specificity required to document an absence of transmission requires an independent confirmatory assay. To meet this need, an independent PCR assay targeting the cytochrome B (cytB) gene of the O. volvulus mitochondrion was developed. This assay could detect O. volvulus mitochondrial DNA purified by magnetic bead capture using the primers for the cytB gene and from the nuclear encoded repeated sequence DNA targeted in the primary assay. These preliminary data suggest that the mitochondrial PCR assay may be employed as a confirmatory assay to detect O. volvulus in pools of vector flies.

Capture Assay

DNA Purification

Mitochondrion

Onchocerciasis

Streptavidin

Public Health

A generic capture assay for immunogenicity, using Biacore

Engqvist, Martin

January 2013

The purpose of this investigation was to create and optimise a capture assay for the detectionof anti-drug antibodies (ADA) in human plasma, using Biacore. We also dealt with the nonspecificplasma binding to mouse-derived anti-biotin which may occur in the capture assay.By paying attention to these things we aimed at reaching as high sensitivity as possible for theADA detection. The capture assay also benefited and gained flexibility from using the same regenerationsolution irrespective of drug and from having a composition that minimises the risk ofdamaging drug epitopes.

Immunogenicity

immunoassay

capture assay

Biacore

non-specific binding

anti-drug antibodies (ADA)

human plasma

anti-biotin

biotinylation

DNA mismatch repair and mutation avoidance in the ciliate protozoan Tetrahymena thermophila

Salsiccioli, Shawn Richard

28 August 2013

The DNA of all organisms is continuously exposed to exogenous and endogenous genotoxic agents. Fortunately, through the concerted actions of several DNA repair and mutation avoidance pathways, DNA damage can be removed and an organism’s genomic stability maintained. DNA base-base mismatches are generated as a result of the inherent replication errors made by the DNA replication machinery, as well as during the meiotic pairing of homologous but non-identical chromosomes. Through the coordinated actions of the highly conserved DNA mismatch repair (MMR) system, these errors are detected, removed and corrected, thus restoring the integrity of the DNA. In the absence of DNA MMR, genetic instability is unavoidable, resulting in the accumulation of mutations, and in mammals, a susceptibility to cancer. To better understand the roles of the MMR system in mutation avoidance during DNA replication, meiosis, and in nuclear apoptosis, we have utilized the nuclear dimorphic, ciliate protozoan Tetrahymena thermophila. We have identified seven putative MMR homologues; two are similar to eukaryotic MLH1 and PMS2, respectively, and five are similar to eukaryotic MutS homologues, one with eukaryotic MSH2 and four with MSH6. Our studies demonstrate that during conjugation, the relative transcript abundance of each MMR homologue is increased compared to vegetatively growing or nutritionally deprived (starved) cells. Also, the expression profile throughout conjugation is bimodal, corresponding to micronuclear (MIC) meiosis and macronuclear (MAC) anlagen development, both periods in which DNA replication occurs. Cells containing macronuclear knockouts of the PMS2, MSH2 and MSH6_1 genes were unable to successfully pair and complete conjugation, but were viable throughout vegetative growth. Cells in which the macronuclear MSH6_2 gene was knocked out had a phenotype that was similar to wild-type cells, during conjugation and vegetative growth. Interestingly, we observed that the MIC of cells containing MAC knockouts of the PMS2 and TML1 genes appear to have decreased copy number of specific “target sequences”, as determined by qPCR using the Random Mutation Capture (RMC) assay. This decrease reflects neither a loss of micronuclei nor a reduction in total micronuclear DNA content. These studies demonstrate that the PMS2, TML1, MSH2, and MSH6_1 homologues are necessary for the maintenance of micronuclear function and stability during conjugal development and vegetative growth, whereas the remaining MSH6 homologues have less pronounced roles in DNA repair and development. Additionally, macronuclear development in Tetrahymena appears less reliant on the DNA mismatch repair system and perhaps uses alternate surveillance mechanisms to maintain genomic stability during asexual and sexual development. / Graduate / 0306 / 0379 / 0307

Mismatch repair

Tetrahymena thermophila

Ciliate

qPCR

Phylogenetics

Micronucleus

Macronucleus

Random Mutation Capture Assay