Genetic and Functional Studies of LociAssociated with Atrial Fibrillation

Gore Panter, Shamone Robinette

January 2014

No description available.

Genetics

Cellular Biology

Molecular Biology

Atrial Fibrillation

Genome wide association studies

gene expression

gene regulation

genomics

PITX2

long non-coding RNAs

Single nucleotide polymorphisms

human embryonic stem cells

Analysis of artificial chromosomes in human embryonic stem cells

Mandegar, Mohammad Ali

January 2011

The development of safe and efficient gene delivery systems in pluripotent human embryonic stem cells (hESc) is essential to realising their full potential for basic and clinical research. The purpose of this study was to develop an efficient, non-integrating gene expression system in pluripotent hESc using human artificial chromosomes (HAC). Similar to endogenous chromosomes, HAC are capable of gene expression, replication and segregation during cell division. Unlike retroviral-mediated gene delivery vectors, HAC do not integrate into the host genome and can encompass large genomic regions for the delivery of multiple genes. Despite the advantages HAC offer, their use has been limited due to laborious cloning procedures and poor transfection efficiencies, and thus only studied in immortalised and tumour-derived human cell lines. In this study, the high transduction efficiency of herpes simplex virus type-1 (HSV-1) amplicons was utilised to overcome the described difficulties and delivered HAC vectors into pluripotent hESc. Analysis of stable hESc clones showed that de novo gene-expressing HAC were present at high frequencies ranging from 10-70% of metaphases analysed, without integrating into the genome. The established HAC contained an active centromere, and were stably maintained without integration or loss in the absence of selection for 90 days. Stable HAC-containing hESc clones retained their pluripotency as demonstrated by neuronal differentiation, in vitro germ layer and teratoma formation assays. HAC gene expression persisted, with some variation, post-differentiation in the various deriving cell types. This is the first report of successful de novo HAC formation in hESc for gene expression studies. These findings show potential for delivering high-capacity genomic constructs safely and efficiently into pluripotent cells for the purpose of genetic manipulation and ultimately patient-specific somatic gene therapy.

617.954

HSV-1 amplicon system for human artificial chromosome formation in human ES/iPS cells and pluripotency induction

Khoja, Suhail

January 2012

Development of safe and efficient approaches for gene delivery in human embryonic stem cells (hESc) and particularly in human induced pluripotent stem (hiPS) cells, which can be derived in a person-specific manner, is considered to be imperative for harnessing their full potential in both the basic and applied research. The aim of this study was to evaluate the potential of human artificial chromosome (HAC) for gene delivery and expression in hESc and hiPS cells. HAC offers many potential advantages including the provision for carrying large genes with corresponding regulatory elements to obtain long-term regulated gene expression. In addition, they can replicate and segregate independently without integration into the host cell genome. To develop HAC in hiPS cells, the first part of the study was aimed at generating hiPS cells utilising the Herpes Simplex Virus (HSV)-1 amplicon system. With the use of EBNA-1/OriP retention elements incorporated into the HSV-1 amplicon vectors, hiPS cells completely free of vector and transgenes sequences were successfully derived from human embryonic fibroblasts. The hiPS cells exhibited proliferation and differentiation potential similar to that of hESc. In the second part of the study, development of HAC in hESc and hiPS cells was assessed by utilising the HSV-1 amplicon system to deliver the HAC DNA. Analysis of the hESc confirmed the presence of functional HAC which replicated the behaviour of the host chromosomes. Additionally, HAC generation did not lead to impairment in the developmental potential and pluripotency of hESc. The hiPS cells supported HAC at low frequency but DNA also integrated into the host chromosomes. The HAC system, therefore, needs further refinements to improve the frequency of HAC formation and reduce the chromosomal integration of HAC constructs in hiPS cells. Overall, these findings provide a simple and safe way of pluripotency induction and genetic modification of pluripotent stem cells using the HSV-1 amplicon system and represent an important advance towards patient specific gene and cell therapy.

616.02774

Modelová studie účinků ultrazvuku na vývoj plodu / Model Study of Ultrasound Effects on Fetal Development

Jaroš, Josef

January 2009

The progress in ultrasound techniques goes hand in hand with increasing of diagnostic machine acoustic outputs. Ultrasound biological effects can adversely influence the development of human fetus. Recent studies of thermal effect on biological tissues are usually based on simulation of simple ultrasound transducers. The aim of this work is to build a flexible model of diagnostic system to simulate temperature increase during fetal development. Different types of ultrasound probes were used for generation of acoustic field with simulated piezoelectric element properties. Optimized linear and phased arrays were modeled with dynamic beam steering and focus. Computer simulations were concentrated on extreme conditions in obstetric ultrasonography and 3D tissue model was compared with real ultrasound probes measurements. To detect temperature increase, the bone tissue phantom was used. Results point out potential risks for fetus with diagnostic ultrasound probes. Based on the results of this work, practical recommendations increasing safety of obstetric examinations were drawn.