Morphological and Gene Expression Changes in Cattle Embryos from Hatched Blastocyst to Early Gastrulation Stages after Transfer of In Vitro Produced Embryos

Leeuwen, Jessica van; Berg, D.K.; Pfeffer, Peter

doi:10.1371/journal.pone.0129787

Cited by 50 publications

(97 citation statements)

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“…Unlike in mouse and human embryos, gastrulation in cattle (and other ungulates) begins prior to implantation and takes place around 16 dpi. Mural TE proliferation causes further embryo extension, which finally reaches up to 20cm in length before the implantation (Degrelle et al, 2005, van Leeuwen et al, 2015. Due to the differences mentioned above, for a long time, it was believed that bovine/ ungulate blastocyst may not be similar to the known mouse or human model of cell differentiation, lineage-specific signalling pathways activity and/or ICM/TE marker gene expression.…”

Section: Mechanisms Of Pluripotency Maintenance In Cattlementioning

confidence: 99%

Beyond the mouse: non-rodent animal models for study of early mammalian development and biomedical research

Madeja

Pawlak²,

Piliszek³

2019

Int. J. Dev. Biol.

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The preimplantation development of mammals generally follows the same plan. It starts with the formation of a totipotent zygote, and through consecutive cleavage divisions and differentiation events leads to blastocyst formation. However, the intervening events may differ between species. The regulation of these processes has been extensively studied in the mouse, which displays some unique features among eutherian mammals. Farm animals such as pigs, cattle, sheep and rabbits share several similarities with one another, and with the human developmental plan. These include the timing of epigenetic reprogramming, the moment of embryonic genome activation and the developmental time-frame. Recently, efficient techniques for genetic modification have been established for large domestic animals. Genome sequences and gene manipulation tools are now available for cattle, pigs, sheep and goats, and a larger number of genetically engineered livestock is now accessible for biomedical research. Yet, these animals still make up less than 0.5% of animals in research, mainly due to our inadequate knowledge of the processes responsible for pluripotency maintenance (to date no stable naïve embryonic stem cell lines have been established) and early development. In this review, we highlight our present knowledge of the key preimplantation events in the 3 non-rodent species which present the highest potential for biomedical research related to early embryonic development: cattle, which offer an excellent model to study human in vitro embryo development, pigs which emerge as models to study the long-term effects of gene-based therapies and rabbits, which in many aspects of embryology resemble the human.

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Section: Mechanisms Of Pluripotency Maintenance In Cattlementioning

confidence: 99%

Beyond the mouse: non-rodent animal models for study of early mammalian development and biomedical research

Madeja

Pawlak²,

Piliszek³

2019

Int. J. Dev. Biol.

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“…However, information from a wider sampling of mammalian species is essential to understand what features are mammo‐typic. More recently, work in rabbit has started to incorporate culture and live imaging experiments while a handful of studies have begun to provide staging systems, EM data, and molecular insight into gastrulation through the expression pattern of key genes in both cow and pig . These species all have substantial differences in early development, including the size and composition of extraembryonic tissues, timing and manner of implantation, but they all have bilaminar blastodiscs prior to gastrulation and can be considered, topographically, to be broadly more representative of mammalian gastrulation than that of the egg‐cylinder morphology of the rodents.…”

Section: Gastrulation In Amniotesmentioning

confidence: 99%

“…These species all have substantial differences in early development, including the size and composition of extraembryonic tissues, timing and manner of implantation, but they all have bilaminar blastodiscs prior to gastrulation and can be considered, topographically, to be broadly more representative of mammalian gastrulation than that of the egg‐cylinder morphology of the rodents. Although the embryos of the species are of approximately similar size prior to gastrulation there are also morphological differences, for example the rabbit blastodisc is a flat oval‐like shape which converts to a pyriform (pear‐like) shape during gastrulation, while in the cow there is an oval blastodisc during the onset of primitive streak formation that proliferates to form a lens‐shaped thickening, and the pig embryo epiblast converts from circular to oval during primitive streak formation . Morphological changes are also seen in the mouse embryo as the cylinder elongates: transverse sections show that it becomes elongated along one axis forming an ellipse‐like shape—the primitive streak then forms at one end of the long axis of the ellipse .…”

Section: Gastrulation In Amniotesmentioning

confidence: 99%

“…In addition to Brachyury expression building from a crescent‐like region at the posterior margin of the epiblast in these three species, there is also evidence that key signaling pathways and tissues are also conserved with that of chick and mouse. Each has an equivalent tissue to the hypoblast/AVE—the AMC in the rabbit, the anterior hyboblast (AHB) of the pig, and the anterior visceral hypoblast (AVH) of the cow, all of which have been shown to have topographical and molecular homology although there are differences in shape between these tissues. Furthermore, gene expression patterns, in addition to Brachyury , are also well conserved including Bmp4 , Nodal , Cer1 in the cow, FoxA2 in the pig, and Nodal , Dkk1 , Wnt3 , Chordin in rabbit .…”

Section: Gastrulation In Amniotesmentioning

confidence: 99%

“…Each has an equivalent tissue to the hypoblast/AVE—the AMC in the rabbit, the anterior hyboblast (AHB) of the pig, and the anterior visceral hypoblast (AVH) of the cow, all of which have been shown to have topographical and molecular homology although there are differences in shape between these tissues. Furthermore, gene expression patterns, in addition to Brachyury , are also well conserved including Bmp4 , Nodal , Cer1 in the cow, FoxA2 in the pig, and Nodal , Dkk1 , Wnt3 , Chordin in rabbit . Together these studies argue that the signaling pathways, gene expression patterns and extraembryonic tissues involved in gastrulation in these mammalian species has been highly conserved and has adapted to a range of morphologies upon the flat blastodisc.…”

Section: Gastrulation In Amniotesmentioning

confidence: 99%

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The evolution of amniote gastrulation: the blastopore‐primitive streak transition

Stower

Bertocchini

2017

WIREs Developmental Biology

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In the animal kingdom, gastrulation, the process by which the primary germ layers are formed involves a dramatic transformation in the topology of the cells that give rise to all of the tissues of the adult. Initially formed as a mono‐layer, this tissue, the epiblast, becomes subdivided through the internalization of cells, thereby forming a two (bi‐laminar) or three (tri‐laminar) layered embryo. This morphogenetic process coordinates the development of the fundamental body plan and the three‐body axes (antero‐posterior, dorso‐ventral, and left‐right) and begins a fundamental segregation of cells toward divergent developmental fates. In humans and other mammals, as well as in avians, gastrulating cells internalize along a structure, called the primitive streak, which builds from the periphery toward the center of the embryo. How these morphogenetic movements are orchestrated and evolved has been a question for developmental biologists for many years. Is the primitive streak a feature shared by the whole amniote clade? Insights from reptiles suggest that the primitive streak arose independently in mammals and avians, while the reptilian internalization site is a structure half‐way between an amphibian blastopore and a primitive streak. The molecular machinery driving primitive streak formation has been partially dissected using mainly the avian embryo, revealing a paramount role of the planar cell polarity (PCP) pathway in streak formation. How did the employment of this machinery evolve? The reptilian branch of the amniote clade might provide us with useful tools to investigate the evolution of the amniote internalization site up to the formation of the primitive streak. WIREs Dev Biol 2017, 6:e262. doi: 10.1002/wdev.262 This article is categorized under: Early Embryonic Development > Fertilization to Gastrulation Early Embryonic Development > Gastrulation and Neurulation Comparative Development and Evolution > Body Plan Evolution

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Epiblast and trophoblast morphogenesis in the pre‐gastrulation blastocyst of the pig. A light‐ and electron‐microscopical study

Harmoush

Tsikolia

Viebahn

2021

Journal of Morphology

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The epiblast of the amniote embryo is of paramount importance during early development as it gives rise to all tissues of the embryo proper. In mammals, it emerges through segregation of the hypoblast from the inner cell mass and subsequently undergoes transformation into an epithelial sheet to create the embryonic disc. In rodents and man, the epiblast cell layer is covered by the polar trophoblast which forms the placenta. In mammalian model organisms (rabbit, pig, several non‐human primates), however, the placenta is formed by mural trophoblast whereas the polar trophoblast disintegrates prior to gastrulation and thus exposes the epiblast to the microenvironment of the uterine cavity. Both, polar trophoblast disintegration and epiblast epithelialization, thus pose special cell‐biological requirements but these are still rather ill‐understood when compared to those of gastrulation morphogenesis. This study therefore applied high‐resolution light and transmission electron microscopy and three‐dimensional (3D) reconstruction to 8‐ to 10‐days‐old pig embryos and defines the following steps of epiblast transformation: (1) rosette formation in the center of the ball‐shaped epiblast, (2) extracellular cavity formation in the rosette center, (3) epiblast segregation into two subpopulations ‐ addressed here as dorsal and ventral epiblast ‐ separated by a “pro‐amniotic” cavity. Ventral epiblast cells form between them a special type of desmosomes with a characteristic dense felt of microfilaments and are destined to generate the definitive epiblast. The dorsal epiblast remains a mass of non‐polarized cells and closely associates with the disintegrating polar trophoblast, which shows morphological features of both apoptosis and autophagocytosis. Morphogenesis of the definitive epiblast in the pig may thus exclude a large portion of bona fide epiblast cells from contributing to the embryo proper and establishes contact de novo with the mural trophoblast at the junction between the two newly defined epiblast cell populations.

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Morphological and Gene Expression Changes in Cattle Embryos from Hatched Blastocyst to Early Gastrulation Stages after Transfer of In Vitro Produced Embryos

Cited by 50 publications

References 53 publications

Beyond the mouse: non-rodent animal models for study of early mammalian development and biomedical research

Beyond the mouse: non-rodent animal models for study of early mammalian development and biomedical research

The evolution of amniote gastrulation: the blastopore‐primitive streak transition

Epiblast and trophoblast morphogenesis in the pre‐gastrulation blastocyst of the pig. A light‐ and electron‐microscopical study

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