Spatiotemporal development of the forebrain in the Dp(16)1Yey/+ mouse model of Down syndrome

Goodliffe, Joseph White

15 June 2016

Down syndrome (DS), or trisomy 21 (Ts21), is the most common genetic developmental disorder with a prevalence of about one in 700 live births. The triplication of human chromosome 21 (Hsa21) that characterizes this disorder results in a constellation of cognitive and physical alterations. The cognitive deficits range from mild to severe, and persist throughout life. Post-mortem studies of individuals with DS have revealed various neuropathologic abnormalities that are thought to underlie cognitive dysfunction, including: disruption of neurogenesis, corticogenesis, synapse formation, and myelination. However, the etiology of these alterations remains largely unknown. In order to elucidate the genetic basis of DS-phenotypes, several mouse models have been developed. The Ts65Dn, Ts1Cje, and Ts16 models, recapitulate DS-related phenotypes and have extended our knowledge of the associated pathological changes. Despite this progress, genetic dissimilarities in mouse models may confound phenotypic comparisons between mouse models and human DS. Specifically, the aforementioned models have a limited subset of triplicated Hsa-21 homologs or contain non-syntenic genes. Recently, a novel mouse model, the Dp(16)1Yey/+ (or Dp16), that has the entire Hsa-21 syntenic region of Mmu16 triplicated and no non-syntenic genes has been developed, suggesting that Dp16 may present phenotypes more closely matching the human disorder. In this study, we present the first comprehensive analysis of Dp16 embryonic, young and adult brains that includes a focus on the proliferative, inhibitory/excitatory neuronal and oligodendrocyte-lineage phenotypes using histological, immunohistochemical, and behavioral assessments. We hypothesize that due to the larger triplicated segment, the Dp16 mouse model better recapitulates DS-related neuropathologies relative to other mouse models. Despite the extended triplication, Dp16 animals lack DS-related embryonic phenotypes, however, behavioral and cellular phenotypes arise during the 2nd week following birth. The Dp16 is the first model of DS to develop postnatal phenotypes in the absence of changes to embryonic brain development, as such, Dp16 may not be a reliable model to further understand brain development in the DS fetus. However, when used in conjuncture with other models, the Dp16 will be a useful tool in understanding the contribution of aneuploidy and gene dosage to DS-phenotypes in mouse models of DS.

Neurosciences

Embryonic development

Trisomy 21

Cloning and annotation of novel transcripts from human embryonic stem cells

Khattra, Jaswinder

05 1900

Both cDNA tag-based and DNA chip hybridization assays have revealed widespread transcriptional activity across mammalian genomes, providing a rich source of novel protein-coding and non-coding transcripts. Annotation and functional evaluation of this undefined transcriptome space represents a major step towards the comprehensive definition of biomolecules regulating the properties of living cells, including embryonic stem cells (ESCs) and their derivatives. In this study I analysed 87 rare mRNA transcripts from human ESCs that mapped uniquely to the human genome, in regions lacking evidence for known genes or transcripts. In addition, the transcripts appeared enriched in the hESC transcriptome as enumerated by serial analysis of gene expression (SAGE). Full-length transcripts corresponding to twelve novel LongSAGE tags were recovered and evaluated with respect to gene structure, protein-coding potential, and gene regulatory features. In addition, transcript abundance was compared between RNA isolated from undifferentiated hESCs and differentiated cells. Analysis of full-length transcripts revealed that the novel ORFs did not exceed a size of 129 amino acids and no matches were observed to well characterized protein domains. Interesting protein level predictions included small disulfide-bonded proteins, known members of which are important in a variety of biological processes. Transcripts evaluated for differential expression by real-time RT-qPCR (Reverse Transcription followed by real-time quantitative Polymerase Chain Reaction) were found to be variably expressed (0.2- to 4.5-fold) in Day-2 or Day-4 retinoic acid-induced differentiation cultures compared to undifferentiated hESCs. Relative quantitation using a universal reference RNA (derived from pooled adult tissues) showed large differences in novel transcript levels (0.002- to 35-fold) compared to hESCs. Collectively, these results provide a detailed analysis of a set of novel hESC transcripts and their abundance in early and adult differentiated cell types, both of which may advance our understanding of the transcriptional events governing stem cell behavior. / Medicine, Faculty of / Medical Genetics, Department of / Graduate

Genetics

mRNA

Embryonic stem cells

Defining the transcriptional and epigenetic signature of mouse embryonic stem cells with compromised developmental potency

Schacker, Maria Anna

January 2019

Mouse embryonic stem (ES) cells have played a crucial role in studying developmental processes and gene function in vivo. They are extremely useful in the generation of transgenic animals as they can be genetically manipulated and subsequently microinjected into blastocyst stage embryos, where they combine with the inner cell mass and contribute to the developing embryo. Some of the resulting pups are chimaeric, consisting of a mixture of cells derived from the host blastocyst and the injected ES cells. We have identified several ES cell clones arising from gene targeting experiments with an impaired capacity to generate viable chimaeras. When injected into blastocysts, these clones cause embryonic death during mid to late gestation, suggesting that the cells are able to contribute to the embryo but interfere with normal embryonic development. The aim of this work was to identify the underlying changes in the transcriptome, epigenome or cell surface markers that have occurred in these compromised ES cells and to further define the developmental phenotype of the chimaeric embryos. Different stages during development were analysed and whereas there was little difference in embryonic death at gestational day e13.5, there was a significant decrease in embryos surviving to gestational day e17.5. Additionally, severe haemorrhaging was observed in all the dead embryos and small foci of haemorrhaging could also be seen in a number of embryos that were still alive. This was also observed at e13.5, albeit to a less severe extent. Using RNA sequencing to discover differences in the transcriptome between control ES cells and the compromised ES cells, five genes were identified that were downregulated in the compromised cells. Four of these, Gtl2, Rtl1as, Rian and Mirg are all located in the imprinted Dlk1-Dio3 region on chromosome 12 and are normally expressed from the maternal genome. This pattern was also validated in tissues from e17.5 chimaeric embryos. The expression of this locus is to a large extent regulated by a differentially methylated region located approximately 13kb upstream of the Gtl2 promoter, the IG-DMR. Whereas this is usually only methylated on the paternal copy, in the compromised ES cells both the paternal and the maternal copy were fully methylated, likely causing the silencing of Gtl2, Rtl1as, Rian and Mirg. Using the DNA methyltransferase inhibitor 5-azacytidine, expression of Gtl2 could be rescued. Injection of those 5-azacytidine treated cells into blastocysts did partially rescue the embryonic lethal phenotype. Additionally, cell surface markers were analysed in a phenotypic screen using phage display. NGS analysis of the phage outputs indicates that there may be additional differences in cell surface markers between the control and compromised ES cell clones, but their specific details remain to be identified. Overall, we have identified the maternally expressed genes of the Dlk1-Dio3 region as markers that can distinguish between ES cells with normal or compromised developmental potency and propose to include these genes in the pre-blastocyst injection screening routine for experiments involving the production of chimaeras or genetically modified mouse strains.

Notch signalling pathway in murine embryonic stem cell derived haematopoiesis

Huang, Caoxin

January 2013

Haematopoiesis is the process to produce haematopoietic stem cells (HSCs), haematopoietic progenitors (HPCs) and terminally differentiated cell types. In the adult, HSCs resided in bone marrow while in the embryo, haematopoiesis occurred sequentially in several niches including yolk sac, aorta-gonad-mesonephros (AGM) region, placenta and fetal liver. The AGM region is the first place where HSCs arise in vivo and therefore should provide important factors to induce haematopoiesis. The mouse embryonic stem cells (mESC) system is a powerful platform to mimic the development process in vitro and is widely utilized to study the underlying mechanisms because they are pluripotent and can be genetically manipulated. A novel co-culture system has been established by culturing differentiating mESCs with primary E10.5 AGM explants and a panel of clonal stromal cell lines derived from dorsal aorta and surrounding mesenchyme (AM) in AGM region. Results of these co-culture studies suggested that the AM-derived stromal cell lines could be a potent resource of signals to enhance haematopoiesis. Molecular mechanism involved in haematopoiesis is a key research direction for understanding the regulation network of haematopoiesis and for further clinical research. A series of studies have demonstrated involvement of the Notch signalling pathway in haematopoiesis during development but with controversial conclusions because of the difference of models concerning various time windows and manipulating populations. This project aimed to investigate the role of Notch signalling pathway during haematopoiesis in the AGM environment. We analyzed the expression of Notch ligands in AGM-derived stromal cells with or without haematopoietic enhancing ability. No correlation was observed between ligand expression and haematopoietic enhancing ability in stromal cell lines or between Notch activity in EBs and haematopoietic enhancing ability. We demonstrated that inhibition of the Notch signalling pathway using the γ-secretase inhibitor could abrogate Notch activity in both mES-derived cells and the haematopoietic enhancing AM stromal cell line. To better understand the involvement of the Notch signalling pathway in a more specific spatial-temporal environment, we established a co-culture system of haemangioblast like cells (Flk1+) with one of AM region derived stromal cell lines with haematopoietic enhancing ability . We found that the AM stromal cell line could enhance Flk1+ derived haematopoiesis as assessed by haematopoietic colony formation activity and production of CD41+cKit+ progenitor cells. Based on the issue that the inhibitor could potentially affect both the ES cells and stromal cells, we carried out genetic approaches to overexpress or knock down Notch signalling pathway in this Flk1+/AM co-culture system. Interestingly, it was found that when Notch activity was enhanced in Flk1+ cells, the production of haematopoietic progenitors was inhibited and the number of cells expressing the pan-haematopoietic marker CD45 was reduced. By using the inducible dominant negative MAML1 system to knock down Notch activity, it was found that the haematopoiesis in the Flk1+/AM co-culture system was not affected, which could be accounted for the low Notch activity in this system. These results supported the hypothesis that the Notch signalling pathway plays a role in modulating Flk1+ derived haematopoietic differentiation within the AGM microenvironment.

616.02

Development of the pharyngeal arches

Veitch, Emma

January 2000

No description available.

590

Activin in early vertebrate and human development

Bartlett, Simon Robert

January 1996

No description available.

611

Investigations into the development of the pronephros of Xenopus laevis

Brennan, Hannah Claire

January 1999

No description available.

590

The allocation of the Malpighian tubule cells of Drosophila melanogaster

Ainsworth, Claire Elise

January 1999

No description available.

590

The role of receptor protein tyrosine phosphatases in axon guidance

Chilton, John K.

January 2000

No description available.

572

Maternally derived growth regulating factors for mammalian embryos during early organogenesis

Tebbs, Caroline Anne

January 1996

No description available.

611