aðeins hærra en sambærilegar erlendar rannsóknir. Marktækur munur er á fj ölda karla og kvenna sem greinast og mætti ætla að það sé vegna íjölda prólaktínóma sem er algengari hjá konum en körlum. Niðurstöður sem valda áhyggjum er hversu margir einstaklingar sem greinst hafa með heiladingulsæxli eru ekki í eftirliti ásamt því sem þó nokkri eru ekki í eftirliti hjá innkirtlaérfræðingi. Þetta er eitthvað sem þyrfti að bæta. Identification and localization of trophoblast progenitor cells in the mouse placenta Elín Maríusdóttirl, Dr J. Cross2, Dr. D. Natale2, Dr. D. Simmons2. lDepartment of Medicine, University of Iceland, 2Department of Developmental Biology - University of Calgary, Calgary Alberta. Introduction: The placenta has a critical role in transferring nutrients and oxygen to the developing fetus. Nutrient transfer occurs across the highly developed placenta villi that form to create massive surface area. Problems concerning villous development or function are the cause of many pregnancy related diseases. Evidence suggests that abnormalities in growth of the placental villi cause growth restriction in the fetus. Low weight at birth is associated with a spectrum of diseases both in childhood and later in life. Studies of the normal growth of the mouse placental villi (called the labyrinth in rodents) after embryonic day (E) 8.5, particularly identifying markers of trophoblast cell progenitors that produce the villi should provide novel insight into placental growth in general. Previous studies suggested the presence of rapidly proliferating progenitor cells that give rise to cells of the expanding labyrinth between E8.5 and E12.5. Furthermore, when cells start to differentiate they start to express Gcml, exit the cell cycle and form syncytial cells that line the developing villi. In this study we hypothesized that the homeobox gene Ehox is a marker for trophoblast progenitor cells. Materials and methods: Histological sections of mouse placentas were selected at random and using in situ hybridization we localized Ehox mRNA expression and compared it with a known marker of cell proliferation, phospho-histone H3 (PPH3 is expressed in cells in mitosis of the cell cycle). PPH3 positive cells were then quantified and also PPH3 positive cells that express Ehox. To assess whether Ehox and Gcml expression co-localized serial sections were compared. Results: Cell counting revealed that around 60% of PPH3 positive cells also express Ehox. Furthermore comparison of serial sections shows that Ehox and Gcml do not appear to co- localize. Conclusions: Ehox and Gcml do not appear to co-localize, which suggests that Ehox is not expressed in differentiated cells. PPH3 is expressed in proliferating cells and a considerable fraction of them express Ehox. We therefore conclude based on expression patterns and cell counting that Ehox mRNA expression is localized to trophoblast progenitor cells in the placenta. Culturing, differentiation and subcloning of human embryonic stem cells Sólveig Helgadóttirl, Janne Jensen2, Jeonghoon Heo2, Snorri S. Thorgeirsson2 lDepartment of Medicine of the University of Iceland, 2Lab of Experimental Carcinogenesis, National Insti- tutes of Health The unique features of embryonic stem cells (ESCs) are their capacity to differentiate into all cell types comprising the organism and their self-renewal potential. High hopes are tied to possible utilization of ESCs, e.g. in drug screening and replacement cell therapy. In 1998 human ESCs (hESCs) were first isolated from the inner cell mass (ICM) of blastocysts of preimplantation embryos. Since then considerable knowledge has been acquired in experimental procedures, including basic cell culturing methods, growth factor treatment, transfection and gene induction. Differentiation of hESCs can be either spontaneous to form embryonic bodies (EBs) or directed. Successful direction of differentiation of hESCs into hematopoietic, neuronal and cardiomyocytic lineages has been reported. Directed differentiation into endoderm has been diíficult to achieve but is of great interest owing to the lack of e.g. pancreatic fi cells and liver cells for transplantation. There are however still many challenges to improve culturing of undifferentiated colonies, eíficiency of directed differentiation, isolation and clonal expansion of homogenous populations of committed cells. The aim with our study was to optimize cell culture conditions to maintain stable, undifferentiated H9 colonies. By revising established protocols we were able to culture cells for multiple passages, both on a feeder cell layer and in a feeder free environment using conditioned media and high doses of basic FGF. We aimed to improve the eíficiency of EB formation and tried several approaches; suspension culturing of colonies in FGF free media, spin down in 96 well non adherent plate performed on single cells and hanging drop culturing of colonies. Suspension culturing proved the most eíficient method, but hanging drop culturing led to formation of cell clusters we assumed to be cardiomyocytes. Spin down culturing provided no viable colonies. Cell differentiation was monitored by microscopic inspection of cell morphology and gene expression. RT-PCR was conducted for sox-17 (early endoderm marker), brachyury (early mesoderm marker), AFP (endoderm marker) and oct-4 (undifferentiated state

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