The design and application of a real-time PCR assay to assess rcDNA and cccDNA produced by HBV during infection

Bloom, Kristie Michelle

30 August 2010

Chronic hepatitis B virus (HBV) infection is endemic to sub-Saharan Africa, and despite the availability of anti-viral agents, there is currently no cure. This double stranded DNA virus is hepatotropic, and active viral replication results in two genomic equivalents, the relaxed circular DNA (rcDNA) and covalently closed circular DNA (cccDNA). The virion encapsulated rcDNA contains a partially synthesised positive DNA stand and a gap region within the negative strand. After infection of hepatocytes, the rcDNA is repaired in the nucleus to form cccDNA. An important objective of HBV therapy is the elimination of cccDNA, as its persistence within hepatocytes has been attributed to chronic HBV infection. Therefore a reliable assay for this replication intermediate is crucial. The objective of this study was to develop a method based on real-time PCR to detect and quantify HBV cccDNA. PCR primers which flank the rcDNA gap were designed to amplify cccDNA whilst primers flanking the pre-S1 region quantify total HBV DNA. Viral DNA was extracted from HepG2.2.15 cells, along with serum and livers from HBV transgenic mice. According to this assay, cccDNA was readily detectable in transgenic mouse livers, but was present at low concentrations in serum samples. The intrahepatic HBV DNA profile of transgenic mice was found to be 40% cccDNA to 60% rcDNA. In HepG2.2.15 cells, only 2% of HBV DNA was cccDNA whilst the majority was in the form of rcDNA. These results were validated using non-radioactive Southern blothybridisation. Additionally, it was established that although RNAi-based effecters inhibit HBV replication, established cccDNA pools were not eliminated. Real-time PCR provides a convenient platform for HBV cccDNA detection as it allows for the rapid simultaneous amplification and quantification of a specific DNA target through either non-specific or specific DNA detection chemistries. In conclusion, this HBV qPCR assay should enable improved monitoring of patients’ responses to antiviral therapy

Hepatitis B virus

Real-time PCR

Covalently closed circular DNA (cccDNA)

Cutaneous Water Loss and Covalently Bound Lipids of the Stratum Corneum in Adult and Nestling House Sparrows (Passer domesticus) from Desert and Mesic Habitats

Clement, Michelle Elaine

27 July 2011

No description available.

Biology

Ecology

Physiology

Zoology

lipids

cutaneous water loss

epidermis

sphingolipids

covalently bound lipids

stratum corneum

Zwitterionic Separation Materials for Liquid Chromatography and Capillary Electrophoresis : Synthesis, Characterization and Application for Inorganic Ion and Biomolecule Separations

Jiang, Wen

January 2003

<p>Liquid Chromatography (LC) and Capillary Electrophoresis (CE) are modern analytical techniques that play very important roles in many areas of modern science such as life science, biotechnology, biomedicine, environmental studies, and development of pharmaceutics. Even though these two techniques have existed and been subjected to studies for several decades, the developments of new separation materials for them are still very important till now in order to meet the different new demands for improvement from other disciplines in science.</p><p>In this doctoral thesis, several novel covalently bonded sulfobetaine type zwitterionic separation materials are synthesized for the application in LC and CE. These materials carry both positively charged quaternary ammonium groups and negatively charged sulfonic groups, which result in a very low net surface charge compared to conventional separation materials with only anionic or cationic functional groups. Consequently, it is possible to employ these materials for separation of different ionic species under mild conditions. The surface properties have also been characterized, mainly by elemental analysis, sorption isotherm, ζ-potential measurements, and spectroscopic methods.</p><p>By using packed zwitterionic columns for liquid chromatography, small inorganic anions or cations, and acidic or basic proteins can be independently and simultaneously separated in a single run using optimal sets of separation conditions. This is a unique property compared to conventional ionic separation material for LC. When fused silica capillaries coated with zwitterionic polymer are used for capillary electrophoresis, good separations can be achieved for solutes as different as inorganic anions, peptides, proteins, and tryptically digested proteins.</p>

Analytical chemistry

Zwitterionic

stationary phase

separation

liquid chromatography

capillary electrophoresis

sulfobetaine

modification

covalently bonded

graft polymerization

ζ-potential

Analytisk kemi

Analytical chemistry

Analytisk kemi

Zwitterionic Separation Materials for Liquid Chromatography and Capillary Electrophoresis : Synthesis, Characterization and Application for Inorganic Ion and Biomolecule Separations

Jiang, Wen

January 2003

Liquid Chromatography (LC) and Capillary Electrophoresis (CE) are modern analytical techniques that play very important roles in many areas of modern science such as life science, biotechnology, biomedicine, environmental studies, and development of pharmaceutics. Even though these two techniques have existed and been subjected to studies for several decades, the developments of new separation materials for them are still very important till now in order to meet the different new demands for improvement from other disciplines in science. In this doctoral thesis, several novel covalently bonded sulfobetaine type zwitterionic separation materials are synthesized for the application in LC and CE. These materials carry both positively charged quaternary ammonium groups and negatively charged sulfonic groups, which result in a very low net surface charge compared to conventional separation materials with only anionic or cationic functional groups. Consequently, it is possible to employ these materials for separation of different ionic species under mild conditions. The surface properties have also been characterized, mainly by elemental analysis, sorption isotherm, ζ-potential measurements, and spectroscopic methods. By using packed zwitterionic columns for liquid chromatography, small inorganic anions or cations, and acidic or basic proteins can be independently and simultaneously separated in a single run using optimal sets of separation conditions. This is a unique property compared to conventional ionic separation material for LC. When fused silica capillaries coated with zwitterionic polymer are used for capillary electrophoresis, good separations can be achieved for solutes as different as inorganic anions, peptides, proteins, and tryptically digested proteins.

Analytical chemistry

Zwitterionic

stationary phase

separation

liquid chromatography

capillary electrophoresis

sulfobetaine

modification

covalently bonded

graft polymerization

ζ-potential

Analytisk kemi

Analytical chemistry

Analytisk kemi

Optimized Production and Purification of LCC DNA Minivectors for Applications in Gene Therapy and Vaccine Development

Sum, Chi Hong

21 January 2014

Linear covalently closed (LCC) DNA minivectors serve to be superior to conventional circular covalently closed (CCC) plasmid DNA (pDNA) vectors due to enhancements to both transfection efficiency and safety. Specifically, LCC DNA minivectors have a heightened safety profile as insertional mutagenesis is inhibited by covalently closed terminal ends conferring double-strand breaks that cause chromosomal disruption and cell death in the low frequency event of chromosomal integration. The development of a one-step, E. coli based in vivo LCC DNA minivector production system enables facile and efficient production of LCC DNA minivectors referred to as DNA ministrings. This novel in vivo system demonstrates high versatility, generating DNA ministrings catered to numerous potential applications in gene therapy and vaccine development. In the present study, numerous aspects pertaining to the generation of gene therapeutics with LCC DNA ministrings have been explored with relevance to both industry and clinical settings. Through systematic assessment of induction duration, cultivation strategy, and genetic/chemical modifications, the novel in vivo system was optimized to produce high yields of DNA ministrings at ~90% production efficiency. Purification of LCC DNA ministrings using anion exchange membrane chromatography demonstrated rapid, scalable purification of DNA vectors as well as its potential in the separation of different DNA isoforms. The application of a hydrogel-based strong Q-anion exchange membrane, with manipulations to salt gradient, constituted effective separation of parental supercoiled CCC precursor pDNA and LCC DNA. The resulting DNA ministrings were employed for the generation of 16-3-16 gemini surfactant based synthetic vectors and comparative analysis, through physical characterization and in vitro transfection assays, was conducted between DNA ministring derived and CCC pDNA derived lipoplexes. Differences in DNA topology were observed to induce differences in particle size and DNA protection/encapsulation upon lipoplex formation. Lastly, the in vivo DNA minivector production system successfully generated gagV3(BCE) LCC DNA ministrings for downstream development of a HIV DNA-VLP (Virus-like particle) vaccine, thus highlighting the capacity of such system to produce DNA ministrings with numerous potential applications.

Évaluation d’une nouvelle approche vaccinale basée sur l’électroporation in vivo d’ADN pour le traitement des hépatites B chroniques / Evaluation of a new vaccinal approach based on DNA delivery by in vivo electroporation for chronic hepatitis B therapy

Khawaja, Ghada

23 March 2012

Malgré l’existence d’un vaccin préventif efficace, l’infection chronique par le virus de l’hépatite B (HBV) demeure un problème majeur de santé publique. La persistance de l’infection par HBV étant clairement associée à des réponses immunitaires insuffisantes, l’immunothérapie par le vaccin à base d’ADN nu, visant à stimuler les réponses humorales et cellulaires, apparaît comme particulièrement pertinente pour la thérapie des hépatites B chroniques. Toutefois, l’efficacité thérapeutique d’une telle stratégie reste limitée chez l’homme, d’où la nécessité d’optimiser cette approche vaccinale pour une utilisation ultérieure en clinique. Ainsi, l’objectif général de ce travail de thèse était d’explorer, avec le modèle du DHBV (« Duck Hepatitis B Virus »), étroitement apparenté au HBV humain, si l’administration du vaccin à ADN par électroporation (EP) pouvait davantage améliorer son efficacité prophylactique et thérapeutique. Nous avons montré, dans un 1er temps chez des canards naïfs, que l’administration du vaccin à ADN par EP permet de potentialiser le pouvoir neutralisant et d’élargir le répertoire épitopique de la réponse humorale dirigée contre la protéine d’enveloppe du DHBV, même avec des doses d’ADN relativement faibles. Dans un 2ème temps, nous avons montré chez des animaux chroniquement infectés par le DHBV, que l’administration par EP du vaccin à ADN ciblant les protéines structurales du DHBV et le DuIFN-γ améliore considérablement l’efficacité thérapeutique du vaccin, notamment au regard de la séroconversion et de la clairance virale. Les résultats ainsi obtenus confirment l’intérêt majeur de cette approche vaccinale pour la thérapie des hépatites B chroniques / Despite the existence of an effective prophylactic vaccine, chronic hepatitis B virus (HBV) infection remains a major public health problem. Since persistence of HBV infection is mostly associated with insufficient immune responses, therefore DNA vaccination capable of activating both humoral and cellular immune responses appears as a pertinent strategy for chronic hepatitis B therapy. However, the efficacy of such therapeutic approach remains limited in humans. Improvement of DNA vaccine efficacy is therefore needed for future therapeutic applications in clinic. The main objective of this thesis was to investigate in the duck hepatitis B virus (DHBV) model, whether the protective and therapeutic efficacy of DNA vaccine can be enhanced using EP-based delivery system. Firstly, we showed in naïve ducks that EP-based delivery was able to improve the dose efficiency of DNA vaccine and to maintain a highly neutralizing, multi-specific B-cell response even with relatively low DNA doses, suggesting that it may be an effective approach for chronic hepatitis B therapy at clinically feasible DNA dose. Secondly, we showed in chronic DHBV-carriers that in vivo EP is able to dramatically enhance the therapeutic potency of DNA vaccine targeting hepadnaviral proteins. Indeed, this approach was able to consistently restore humoral immune response and to sustainably decrease and even clear viral infection. Thus, these data strongly support the use of this approach for chronic hepatitis B therapy in humans

Vaccin à ADN

Électroporation

HBV (Virus de l'Hépatite B)

DHBV (Duck Hepatitis B Virus)

ADNccc (AND Viral superenroulé)

Réponses immunitaires anti-virales

Neutralisation

Épitopes B

DNA vaccination

Electroporation

HBV (Hepatitis B Virus)

DHBV (Duck Hepatitis B Virus)

CccDNA (Covalently Closed Circular DNA)

Anti-viral immune response

Neutralization

B cells epitopes

616.91