Analysis of gene expression during early development of the zebrafish, Brachydanio rerio

Blader, Patrick

January 1995

No description available.

590

Embryo patterning; Fish

Analysis of embryonic development in Tribolium castaneum using a versatile live fluorescent labelling technique

Benton, Matthew Alan

January 2014

Studies on new arthropod models are shifting our knowledge of embryonic patterning and morphogenesis beyond the Drosophila paradigm. In contrast to Drosophila, most insect embryos exhibit the short or intermediate-germ type and become enveloped by extensive extraembryonic membranes. The genetic basis of these processes has been the focus of active research in several insects, especially Tribolium castaneum. The processes in question are very dynamic, however, and to study them in depth we require advanced tools for fluorescent labelling of live embryos. In my work, I have used a transient method for strong, homogeneous and persistent expression of fluorescent markers in Tribolium embryos, labelling the chromatin, membrane, cytoskeleton or combinations thereof. I have used several of these new live imaging tools to study the process of cellularisation in Tribolium, and I found that it is strikingly different to what is seen in Drosophila. I was also able to define the stage when cellularisation is complete, a key piece of information that has been unknown until now. Lastly, I carried out extensive live imaging of embryo condensation and extraembryonic tissue formation in both wildtype embryos, and embryos in which caudal gene function was disrupted by RNA interference. Using this approach, I was able to describe and compare cell and tissue dynamics in Tribolium embryos with wild-type and altered fate maps. As well as uncovering several of the cellular mechanisms underlying condensation, I have proposed testable hypotheses for other aspects of embryo formation. The work presented in this thesis will serve as a foundation for future studies on cellularisation and tissue morphogenesis in Tribolium. Furthermore, the live imaging method, the fluorescent labelling constructs, and the analysis I carried out should be easily adaptable to other non-model arthropod species.

590

Gene expression profiling reveals novel attributes of the mouse definitive endoderm

McKnight, Kristen Dawn

05 1900

Gastrulation is one of the most critical events of embryogenesis, generating the three primary germ layers (definitive endoderm, mesoderm, and ectoderm) and establishing the embryonic body plan. The definitive endoderm, which generates the lungs, liver, pancreas, and digestive tract, has become a tissue of particular interest in recent years. Understanding definitive endoderm formation and patterning will greatly aid progress in the in vitro differentiation of embryonic stem cells to definitive endoderm for use in treatment of diseases such as diabetes and hepatitis as an alternative for whole organ replacement. Gene targeting studies have demonstrated a critical role for the Nodal signaling pathway and the forkhead transcription factors Foxh1 and Foxa2 in specification of a group of cells referred to as the anterior primitive streak (APS). However, the transcriptional targets of Foxh1 and/or Foxa2 other than Nodal that regulate specification of this group of cells are currently unknown. Fate mapping and lineage tracing experiments have shown the APS to be the source of the definitive endoderm. However, many questions regarding specification and patterning of the definitive endoderm remain. The study of this tissue has been hampered by the lack of genetic markers specific for the definitive endoderm as many of the current markers, including Cerl, Foxa2, and Sox17, are also expressed in the visceral endoderm, an extraembryonic tissue. To further investigate the role of Foxh1 in specification of the anterior primitive streak and to address the lack of genetic markers for the definitive endoderm we performed expression profiling on post-implantation mouse embryos using Affymetrix™ GeneChips®. From this analysis we identified and characterized a novel marker of the mouse definitive endoderm. Examination of this, and other, novel endoderm markers in Foxh1 and Foxa2 deficient mouse embryos revealed that contrary to current models of definitive endoderm formation, we find some definitive endoderm is formed in these mutants. Specifically, specification of the midgut and hindgut definitive endoderm is largely unaffected, while foregut formation is severely affected. These results suggest that the formation of the midgut and hindgut definitive endoderm populations is independent of the anterior primitive streak and separate from the foregut definitive endoderm. This represents a major insight into the mechanisms regulating endoderm formation and patterning.

Definitive endoderm

Gastrulation

Embryo patterning

Foxh1

Foxa2

Nodal

Gene expression profiling reveals novel attributes of the mouse definitive endoderm

McKnight, Kristen Dawn

05 1900

Gastrulation is one of the most critical events of embryogenesis, generating the three primary germ layers (definitive endoderm, mesoderm, and ectoderm) and establishing the embryonic body plan. The definitive endoderm, which generates the lungs, liver, pancreas, and digestive tract, has become a tissue of particular interest in recent years. Understanding definitive endoderm formation and patterning will greatly aid progress in the in vitro differentiation of embryonic stem cells to definitive endoderm for use in treatment of diseases such as diabetes and hepatitis as an alternative for whole organ replacement. Gene targeting studies have demonstrated a critical role for the Nodal signaling pathway and the forkhead transcription factors Foxh1 and Foxa2 in specification of a group of cells referred to as the anterior primitive streak (APS). However, the transcriptional targets of Foxh1 and/or Foxa2 other than Nodal that regulate specification of this group of cells are currently unknown. Fate mapping and lineage tracing experiments have shown the APS to be the source of the definitive endoderm. However, many questions regarding specification and patterning of the definitive endoderm remain. The study of this tissue has been hampered by the lack of genetic markers specific for the definitive endoderm as many of the current markers, including Cerl, Foxa2, and Sox17, are also expressed in the visceral endoderm, an extraembryonic tissue. To further investigate the role of Foxh1 in specification of the anterior primitive streak and to address the lack of genetic markers for the definitive endoderm we performed expression profiling on post-implantation mouse embryos using Affymetrix™ GeneChips®. From this analysis we identified and characterized a novel marker of the mouse definitive endoderm. Examination of this, and other, novel endoderm markers in Foxh1 and Foxa2 deficient mouse embryos revealed that contrary to current models of definitive endoderm formation, we find some definitive endoderm is formed in these mutants. Specifically, specification of the midgut and hindgut definitive endoderm is largely unaffected, while foregut formation is severely affected. These results suggest that the formation of the midgut and hindgut definitive endoderm populations is independent of the anterior primitive streak and separate from the foregut definitive endoderm. This represents a major insight into the mechanisms regulating endoderm formation and patterning.

Definitive endoderm

Gastrulation

Embryo patterning

Foxh1

Foxa2

Nodal

Gene expression profiling reveals novel attributes of the mouse definitive endoderm

McKnight, Kristen Dawn

05 1900

Gastrulation is one of the most critical events of embryogenesis, generating the three primary germ layers (definitive endoderm, mesoderm, and ectoderm) and establishing the embryonic body plan. The definitive endoderm, which generates the lungs, liver, pancreas, and digestive tract, has become a tissue of particular interest in recent years. Understanding definitive endoderm formation and patterning will greatly aid progress in the in vitro differentiation of embryonic stem cells to definitive endoderm for use in treatment of diseases such as diabetes and hepatitis as an alternative for whole organ replacement. Gene targeting studies have demonstrated a critical role for the Nodal signaling pathway and the forkhead transcription factors Foxh1 and Foxa2 in specification of a group of cells referred to as the anterior primitive streak (APS). However, the transcriptional targets of Foxh1 and/or Foxa2 other than Nodal that regulate specification of this group of cells are currently unknown. Fate mapping and lineage tracing experiments have shown the APS to be the source of the definitive endoderm. However, many questions regarding specification and patterning of the definitive endoderm remain. The study of this tissue has been hampered by the lack of genetic markers specific for the definitive endoderm as many of the current markers, including Cerl, Foxa2, and Sox17, are also expressed in the visceral endoderm, an extraembryonic tissue. To further investigate the role of Foxh1 in specification of the anterior primitive streak and to address the lack of genetic markers for the definitive endoderm we performed expression profiling on post-implantation mouse embryos using Affymetrix™ GeneChips®. From this analysis we identified and characterized a novel marker of the mouse definitive endoderm. Examination of this, and other, novel endoderm markers in Foxh1 and Foxa2 deficient mouse embryos revealed that contrary to current models of definitive endoderm formation, we find some definitive endoderm is formed in these mutants. Specifically, specification of the midgut and hindgut definitive endoderm is largely unaffected, while foregut formation is severely affected. These results suggest that the formation of the midgut and hindgut definitive endoderm populations is independent of the anterior primitive streak and separate from the foregut definitive endoderm. This represents a major insight into the mechanisms regulating endoderm formation and patterning. / Medicine, Faculty of / Medical Genetics, Department of / Graduate

Definitive endoderm

Gastrulation

Embryo patterning

Foxh1

Foxa2

Nodal