Quantification of functionalised gold nanoparticle-targeted knockdown of gene expression in HeLa cells

Introduction: Gene therapy continues to grow as an important area of research, primarily because of its potential in the treatment of disease. One significant area where there is a need for better understanding is in improving the efficiency of oligonucleotide delivery to the cell and indeed, following delivery, the characterization of the effects on the cell. Methods: In this report, we compare different transfection reagents as delivery vehicles for gold nanoparticles functionalized with DNA oligonucleotides, and quantify their relative transfection efficiencies. The inhibitory properties of small interfering RNA (siRNA), single-stranded RNA (ssRNA) and single-stranded DNA (ssDNA) sequences targeted to human metallothionein hMT-IIa are also quantified in HeLa cells. Techniques used in this study include fluorescence and confocal microscopy, qPCR and Western analysis. Findings: We show that the use of transfection reagents does significantly increase nanoparticle transfection efficiencies. Furthermore, siRNA, ssRNA and ssDNA sequences all have comparable inhibitory properties to ssDNA sequences immobilized onto gold nanoparticles. We also show that functionalized gold nanoparticles can co-localize with autophagosomes and illustrate other factors that can affect data collection and interpretation when performing studies with functionalized nanoparticles. Conclusions: The desired outcome for biological knockdown studies is the efficient reduction of a specific target; which we demonstrate by using ssDNA inhibitory sequences targeted to human metallothionein IIa gene transcripts that result in the knockdown of both the mRNA transcript and the target protein. © 2014 Jiwaji et al.

RECQ5 promotes recombination and mutagenesis at targeted nicks through disruption of RAD51 filaments

Thesis (Ph.D.)--University of Washington, 2016-08

Elaboration et analyse de molécules inhibitrices de protéines de la réparation de l’ADN par recombinaison homologue

Les cellules humaines sont soumises à des stress induisant des cassures double-brin de l’ADN (CDB). Ces CDB sont réparées notamment par la recombinaison homologue, impliquant les protéines RAD51 et RAD52. Une stratégie thérapeutique émergente est de développer des molécules inhibant RAD51 ou RAD52 afin d’accentuer l’instabilité génétique et la mort de la cellule cancéreuse. En effet, dans certains cancers, l’activité de RAD51 est dérégulée promouvant la prolifération tumorale. Il existe plusieurs molécules inhibitrices de RAD51 et nous nous sommes intéressés au DIDS dont le mode d’action n’a pas encore été déterminé. Concernant RAD52, une létalité synthétique a été montrée lorsque celle-ci est inactivée dans des cellules déficientes en BRCA1, BRCA2 ou PALB2, trois gènes mutés dans de nombreux cancers. Récemment, trois types de molécules inhibitrices de RAD52 ont été mis en évidence. Nous avons tout d’abord étudié l’impact du DIDS ainsi que des molécules dérivées afin de comprendre le mécanisme mis en jeu. Nous avons montré que le DIDS, ainsi que ses dérivés inhibent la liaison de RAD51 à l’ADN. Ces molécules empêchent la formation du nucléofilament entrainant une diminution du nombre de foyers RAD51. Nous avons développé une méthode de criblage par fluorescence pour évaluer l’effet d’une banque de 696 molécules sur la capacité de RAD52 à hybrider deux ADNsb. Deux molécules capables d’inhiber la fonction d’hybridation de RAD52 ont été mises au jour. In vivo, elles entrainent une diminution de la survie de cellules déficientes en PALB2. La recherche et le développement de nouveaux inhibiteurs de RAD51 et RAD52 constituent des stratégies thérapeutiques d’avenir.

Helicase binding to DnaI exposes a cryptic DNA-binding site during helicase loading in Bacillus subtilis

The Bacillus subtilis DnaI, DnaB and DnaD proteins load the replicative ring helicase DnaC onto DNA during priming of DNA replication. Here we show that DnaI consists of a C-terminal domain (Cd) with ATPase and DNA-binding activities and an N-terminal domain (Nd) that interacts with the replicative ring helicase. A Zn2+-binding module mediates the interaction with the helicase and C67, C70 and H84 are involved in the coordination of the Zn2+. DnaI binds ATP and exhibits ATPase activity that is not stimulated by ssDNA, because the DNA-binding site on Cd is masked by Nd. The ATPase activity resides on the Cd domain and when detached from the Nd domain, it becomes sensitive to stimulation by ssDNA because its cryptic DNA-binding site is exposed. Therefore, Nd acts as a molecular 'switch' regulating access to the ssDNA binding site on Cd, in response to binding of the helicase. DnaI is sufficient to load the replicative helicase from a complex with six DnaI molecules, so there is no requirement for a dual helicase loader system.

A genome editing approach to the study of Parvovirus B19

Parvovirus B19 (B19V) is a ssDNA virus, with a 5596 nt long genome encapsidated within an icosahedral capsid with a diameter of 22 nm. Viral proteins are subdivided into structural and non-structural: the main non-structural one is the NS1, while the 2 structural proteins VP1 and VP2 assemble originating the capsid shell. B19V tropism is mainly limited to erythroid progenitor cells (EPCs), however, virus can be detected in several districts persisting in tissues possibly lifelong. The virus can induce anemia and erythroid aplasia. Therapeutic strategies are only symptomatic, so the search for antivirals is strongly active, with screenings showing the activity in vitro of different compounds like hydroxyurea, cidofovir and brincidofovir. In the first project, a functional minigenome of B19V was developed, able to express only the NS1 protein. This minigenome proved able to replicate and express the NS1 at levels comparable to unmodified clones. Furthermore, the ability of this minigenome to complement the function of NS1-deficient genomes was demonstrated, thus providing a proof-of-concept of B19V genome editing possibility and, at the same time, a useful tool to study the NS1 protein also as an antiviral target. In the second project I addressed the interplay between B19V and the cellular restriction factor APOBEC3B (A3B), a cytidine deaminase acting on ssDNA, whose footprint on B19V genome was proved by a bioinformatic sequence analysis performed by the hosting lab. To understand whether A3B still exerts activity and a potential antiviral effect on B19V, the UT7/EpoS1 cells were transduced with lentiviral vectors to silence A3B expression, then used as a model to study viral behavior. No significant role of A3B on B19V was demonstrated, in agreement with the hypothesis of viral adaptation to this cellular restriction factor; anyway, virus ability to alter A3B expression would deserve further investigations.