Academic literature on the topic '060803 Animal Developmental and Reproductive Biology'

This paper offers a framework to help animal scientists engage in critical thinking about their own practices. Its objective is to reinforce their ability to participate in debates and discussions about the ethics surrounding the use of modern animal reproductive technologies (ART). This will be achieved first by exploring some of the most important philosophical conceptualizations of animals in Western philosophy, which are shaping the way humans interact with them. Then, we will analyse whether modern ART constitute ethically significant innovations in comparison with more traditional animal breeding practices, or whether they stand in continuity with the latter. This will be followed by a review some of the most important ethical issues with modern ART, where human, animal welfare, environmental and socio-economic issues will be discussed.

Metazoan life cycles can be complex in different ways. A number of diverse phenotypes and reproductive events can sequentially occur along the cycle, and at certain stages a variety of developmental and reproductive options can be available to the animal, the choice among which depends on a combination of organismal and environmental conditions. We hypothesize that a diversity of phenotypes arranged in developmental sequence throughout an animal's life cycle may have evolved by genetic assimilation of alternative phenotypes originally triggered by environmental cues. This is supported by similarities between the developmental mechanisms mediating phenotype change and alternative phenotype determination during ontogeny and the common ecological condition that favour both forms of phenotypic variation. The comparison of transcription profiles from different developmental stages throughout a complex life cycle with those from alternative phenotypes in closely related polyphenic animals is expected to offer critical evidence upon which to evaluate our hypothesis.

Assisted Reproductive Technologies (ART) offer a wide range of techniques that have the potential to augment efforts to conserve and manage endangered amphibians and improve wild and captive population numbers. Gametes and tissues of species nearing endangered or extinct status can be cryopreserved and stored in gene banks, to provide material that can be utilised in the future as ART methods are refined. The Spotted Grass Frog, Limnodynastes tasmaniensis, is an abundant amphibian species in South-Eastern Australia of the family Myobatrachidae, that is suitable for the development of ART systems that can be applied to the threatened and endangered myobatrachid and other amphibian species native to Australia. The aim of this study was to advance the understanding of ovulation, fertilisation and embryo nic development of Lim. tasmaniensis and in vitro manipulations of reproduction and development for use in the development of advanced ART procedures such as intracytoplasmic spermatozoon injection (ICSI), androgenesis and nuclear transfer. Ovulation in amphibians can be induced by protocols utilising natural or synthetic hormones. All protocols tested on Lim. tasmaniensis in this study required two injections and the most effective protocols continued to require a first injection of pituitary extracts to induce ovulation. The second injection was, however, successfully replaced by synthetic chorionic gonadotrophin at a threshold dosage of 100 iu and halved the number of cane toads required to source the pituitaries. A combination of LHRH and Pimozide offered a less effective protocol, that did not require the use of pituitary extracts, and avoided the risk of pathogen transfer associated with unsterilised pituitary extracts. Unfertilised eggs of Lim. tasmaniensis were exposed to media of various osmolalities to determine media effects on eggs and their surrounding jelly layers that might impact on egg viability and fertilisability. Osmolality had no effect upon the egg diameter, however, rapid swelling of the jelly layers occurred within 15 minutes of exposure to various media treatments and plateaued from 30-90 minutes without further expansion. Swelling of the jelly layers was increased in hypotonic media (2.5% SAR, H2O) and minimised in the isotonic media (100% SAR). The optimal conditions for the culture of Lim. tasmaniensis eggs were identified as a holding media of 100% SAR, followed by a medium change to 2.5% SAR at insemination. This sequence of media minimised the rate of swelling of the jelly layers prior to contact with the spermatozoa, and maximised the activation of spermatozoa and eggs throughout fertilisation and embryonic development. Embryos of Lim. tasmaniensis were cultured at four temperatures (13 C, 17 C, 23 C and 29 C), to determine the effect of temperature on cleavage and embryonic development rates. Embryonic development progressed through a sequence of stages that were not altered by changes in temperature. However cleavage rates were affected by changes in temperature as compared with normal embryonic growth at 23 C. Embryonic development was suspended at the lowest temperature (13 C) while embryonic viability was maintained. A moderate decrease in temperature (17 C) slowed cleavage, while the highest temperature (29 C) increased the cleavage rate, but decreased the embryo survival. Rates of embryonic development can be manipulated by changes in temperature and this method can be used to source blastomeres of a specific size/stage at a predetermined age or halt cleavage at specific stages for embryos or embryo derived cells to be included in ART procedures. This study produced the first report of the application of Intracytoplasmic Spermatozoon Injection (ICSI) in an Australian amphibian. Eggs that were activated by microinjection with a single spermatozoon (n=50) formed more deep, but abnormal, cleavage furrows post-injection (18/50, 36%), than surface changes (12/50, 24%). This result is in contrast to eggs injected without a spermatozoon (n=42), where the majority of eggs displayed limited surface changes (36/42, 86%), and few deep, abnormal furrows (3/42, 7%). Three advanced embryos (3/50, 6%) were produced by ICSI that developed to various stages within the culture system. Technical difficulties were encountered that prevented the generation of any metamorphs from ICSI tadpoles. Nevertheless, when these blocks to ICSI are overcome, the ICSI procedure will be both directly useful as an ART procedure in its own right, and the associated refinement of micromanipulation procedures will assist in the development of other ART procedures in Lim. tasmaniensis. A greater understanding of basic reproductive and developmental biology in Lim. tasmaniensis would greatly facilitate refinement of fertilisation by ICSI. Assisted Reproductive Technologies, in conjunction with gene banks may in the future regenerate extinct amphibian species, and assist in the recovery of declining amphibian populations nationally and worldwide.

L’environnement façonne la physiologie, la morphologie et le comportement des organismes par l’entremise de processus écologiques et évolutifs complexes et multidimensionnels. Le succès reproducteur des animaux est déterminé par la valeur adaptative d’un phénotype dans un environnement en modification constante selon une échelle temporelle d’une à plusieurs générations. De plus, les phénotypes sont façonnés par l’environnement, ce qui entraine des modifications adaptatives des stratégies de reproduction tout en imposant des contraintes. Dans cette thèse, considérant des punaises et leurs parasitoïdes comme organismes modèles, j’ai investigué comment plusieurs types de plasticité peuvent interagir pour influencer la valeur adaptative, et comment la plasticité des stratégies de reproduction répond à plusieurs composantes des changements environnementaux (qualité de l’hôte, radiation ultraviolette, température, invasion biologique). Premièrement, j’ai comparé la réponse comportementale et de traits d’histoire de vie à la variation de taille corporelle chez le parasitoïde Telenomus podisi Ashmead (Hymenoptera : Platygastridae), démontrant que les normes de réaction des comportements étaient plus souvent positives que celles des traits d’histoires de vie. Ensuite, j’ai démontré que la punaise prédatrice Podisus maculiventris Say (Hemiptera : Pentatomidae) peut contrôler la couleur de ses œufs, et que la pigmentation des œufs protège les embryons du rayonnement ultraviolet; une composante d’une stratégie complexe de ponte qui a évoluée en réponse à une multitude de facteurs environnementaux. Puis, j’ai testé comment le stress thermique affectait la dynamique de la mémoire du parasitoïde Trissolcus basalis (Wollaston) (Hymenoptera : Platygastridae) lors de l’apprentissage de la fiabilité des traces chimiques laissées par son hôte. Ces expériences ont révélé que des températures hautes et basses prévenaient l’oubli, affectant ainsi l’allocation du temps passé par les parasitoïdes dans des agrégats d’hôtes contenant des traces chimiques. J’ai aussi développé un cadre théorique général pour classifier les effets de la température sur l’ensemble des aspects comportementaux des ectothermes, distinguant les contraintes des adaptations. Finalement, j’ai testé l’habileté d’un parasitoïde indigène (T. podisi) à exploiter les œufs d’un nouveau ravageur invasif en agriculture, Halyomorpha halys Stål (Hemiptera : Pentatomidae). Les résultats ont montré que T. podisi attaque les œufs de H. halys, mais qu’il ne peut s’y développer, indiquant que le ravageur invasif s’avère un « piège évolutif » pour ce parasitoïde. Cela pourrait indirectement bénéficier aux espèces indigènes de punaises en agissant comme un puits écologique de ressources (œufs) et de temps pour le parasitoïde. Ces résultats ont des implications importantes sur la réponse des insectes, incluant ceux impliqués dans les programmes de lutte biologique, face aux changements environnementaux.
The environment shapes the physiology, morphology, and behaviour of organisms through complex, multidimensional ecological and evolutionary processes. The reproductive success of individual animals is determined by how well their phenotype is suited to an environment that is constantly changing over single and multi-generational time scales. At the same time, phenotypes are shaped by the environment, which triggers adaptive modifications of animal reproductive strategies while also imposing important constraints. In this thesis, using stink bugs and their parasitoids as model organisms, I considered how several types of plasticity can interact to influence biological fitness, and how plasticity in reproductive strategies responds to several important components of environmental change (host quality, ultraviolet radiation, temperature, biological invasions). Firstly, I compared the response of behavioural and life history traits to body size variation in the parasitoid Telenomus podisi Ashmead (Hymenoptera: Platygastridae), finding that reaction norms of behavioural traits more often had positive slopes than life history traits. Next, I found that the predatory stink bug Podisus maculiventris Say (Hemiptera: Pentatomidae) can selectively control the colouration of its eggs. Egg pigmentation in this species protects embryos against ultraviolet radiation as part of a complex oviposition strategy that evolved in response to a suite of environmental factors. Then, I tested how thermal stress affects the memory dynamics of the parasitoid Trissolcus basalis (Wollaston) (Hymenoptera: Platygastridae) learning the reliability of chemical traces left by its host. These experiments revealed that both high and low stressful temperatures prevented forgetting, affecting the time allocation of parasitoids on patches of host chemical traces. I also developed a general framework to classify temperature’s effects on all aspects of ectotherm behaviour, distinguishing constraints from adaptive behavioural adjustments. Finally, I tested the ability of an indigenous parasitoid (T. podisi) to attack the eggs of a new invasive pest of agriculture, Halyomorpha halys Stål (Hemiptera: Pentatomidae). The results showed that T. podisi attacks the eggs of H. halys but cannot develop, demonstrating that the invasive pest is an “evolutionary trap” for indigenous parasitoids, which could indirectly benefit native stink bug species by acting as an egg and time sink for the parasitoid. These findings have important implications for how insects, including those involved in biological control programs, respond to environmental change.

During gestation, the maternal liver undergoes various adaptive changes to cope with the increasing physiological and metabolic demands from both maternal and fetal compartments. Among these changes are robust growth and changes in transcriptome profile. However, how these events happen, and other aspects of this physiological phenomenon remains unexplored. Therefore, we aimed at further understanding how maternal liver responds to pregnancy. We used BrdU labeling combined with a virus-based tracing approach to quantify the percentage of maternal hepatocytes undergoing DNA synthesis and division over the course of gestation in mice.

We found that ~50% maternal hepatocytes entered S-phase but, unexpectedly, did not undergo cytokinesis. This strongly suggests that maternal hepatocytes in fact undergo endoreplication instead of hyperplasia, as believed previously. Pericentral Axin2⁺ hepatocytes were reported to behave as liver stem cells responsible for liver homeostasis and turnover. We generated an in vivo fate-tracing mouse model to monitor the behavior of these cells in the maternal liver. Our results showed that they did not proliferate during pregnancy, homeostasis, and following partial hepatectomy. Curiously, we uncovered that, hepatocytes exhibit developmental phenotypes at mRNA level pre-pregnancy and at both mRNA and protein level during pregnancy. In the non-pregnant state, hepatocytes reserved mRNA expression of liver progenitor marker genes Cd133 and Afp, which are localized in the nuclei, without protein translation. During gestation, maternal hepatocytes displayed cytoplasmic translocation of Cd133 and Afp transcripts, concomitant with corresponding protein expression.

Overall, all maternal hepatocytes became CD133⁺, and a subset of them express AFP. Additionally, in non-pregnant livers, mRNA of Epcam, another liver progenitor marker, was expressed within majority of hepatocytes, whereas its protein was solely translated in the pericentral region. In contrast, by end-gestation, EPCAM protein expression switched to the periportal region. These observations indicate that maternal hepatocytes exhibit heterogeneous developmental phenotypes, partially resembling fetal hepatocytes. It is intriguing why mature hepatocytes dedifferentiate into a progenitor state in response to pregnancy. AFP is considered to be produced primarily from fetal liver and thus is used to evaluate fetal development health.

A potential clinical relevance of our data is that we identified maternal liver as a new source of AFP. The hippo signaling pathway has been shown to potently control liver growth and hepatocyte heterogenicity. Surprisingly, we found that pregnancy neither altered the expression nor activities of the components of this pathway and its effector YAP1/TAZ. This finding indicates that pregnancy-induced maternal liver growth is not driven by hippo-YAP1 pathway. However, we demonstrate that the presence of YAP1 is essential for CD133 protein expression in maternal hepatocytes. Collectively, we revealed that, as pregnancy advances, maternal hepatocytes likely undergo endoreplication and display developmental phenotypes. Mechanistically, YAP1 dictates the expression of CD133, contributing to the pregnancy-dependent phenotypic changes of maternal hepatocytes.

The production of developmentally competent in vitro derived embryos is necessary to decreasing both economic and emotional losses. Epigenetic abnormalities/insults have been shown to occur at a higher incidence in in vitro embryos. An increased prevalence of epigenetic derived disorders such as Parkinson’s disease, Prader-Willi syndrome, and α-thalassemia as well as elevated preimplantation embryo arrest and reduced developmental rates are theorized to be caused by errors in the mediation of chromatin remodeling. Chromatin remodeling refers to the restructuring of packaged DNA so that transcription factors are either given more or less access to specific sequences. This can be done by covalent modification through histone methylation, acetylation, and phosphorylation as well as noncovalent modifications which employ ATP dependent chromatin remodeling complexes. The purpose of this thesis was to characterize two structurally integral core subunits, BAF155 and BAF170, of the SWI/SNF chromatin remodeling complex in porcine oocytes and preimplantation embryos.

The first study concentrated on the transcript abundance of BAF155 and BAF170 in porcine oocytes and embryos. First, BAF155 and BAF170 transcript sequences were identified in porcine muscle and heart tissues. Those sequences were used to create quantitative polymerase chain reaction (qPCR) primers. mRNA from pools of GV oocytes (100-800) was converted to cDNA for transcript abundance measurements. However, transcript abundance remained too low for either BAF155 or BAF170 to be accurately quantified.

The second study focused on developmental competency of embryos post interfering RNA (RNAi) knockdown of BAF155, BAF170, or both BAF155/BAF170 combined. After 7 days of culture, an analysis of variance (ANOVA) was performed to determine differences in mean nuclei numbers and morphological blastocyst percentages across the three groups. No significant difference was seen between means of treatment groups vs. both control groups. Significant differences were seen between siRNA and Non-Injected groups as well as Non-Injected and Scramble RNA groups. However this indicates that loss of BAF155, BAF170, or a combination of the two transcripts is not the driving force of the significant differences, rather the microinjection itself caused the differences.

The third study examined the process by which BAF155 and BAF170 proteins are imported from the cytoplasm into the nucleus. It was hypothesized that karyopherin α 7 (KPNA7), a nuclear importer known to be prevalent in the porcine oocyte and early embryo, is the main importer of both subunits. A dominant-negative KPNA7 construct missing the importin beta binding (IBB) domain was microinjected into parthenogenetically activated embryos to outcompete competent wild-type KPNA7. No change in protein localization was seen at the 4-cell stage of development (48 hours post-injection) for either BAF155 or BAF170. To reinforce these results, an RNAi targeting KPNA7 was also microinjected into parthenogenetically activated embryos. Again, no change was shown in protein localization at the 4-cell stage (48 hours post-injection), indicating that KPNA7 was not the main nuclear importer of either BAF155 or BAF170.

Further study is necessary to determine transcript abundance and the mechanism of nuclear import of both BAF155 and BAF170.

The need to protect size and age structures from selective harvest in order to maintain sustainable fish stocks has been emphasized in recent literature. The Big Old Fat Fecund Female Fish (BOFFFF) hypothesis has been influential in discussions of changing stock management strategies, and postulates that larger, older females have a disproportionate input into stock recruitment due to physiological advantages. In this study, we utilize a meta-analysis approach to test the assumption of the BOFFFF hypothesis, that larger female fish produce larger eggs and more viable offspring, at a broad scale. Following the meta-analyses, we assess whether larger females from a subset of studies use their gonadal investment more efficiently than small females. From our meta-analyses, we found positive, significant intraspecific relationships between female size and egg size. Moreover, we found positive associations between egg size and offspring viability (offspring size and survival). However, we found in a subset of studies that although proportional survival of offspring often increases with egg size, females that produced larger eggs yielded fewer surviving offspring per unit gonadal investment. This reduced efficiency in reproductive investment is a product of the trade-off between egg size and fecundity. We conclude that although larger females may appear to produce more viable individual offspring, their input to stock recruitment, according to total stock gonadal biomass, may not be disproportionate, as stated by the BOFFFF hypothesis. However, we did not account for whether the benefits of maternal effects extend beyond the larval stage.

The theory of optimal egg size implies that fish trade off between fecundity and individual gonad investment according to their environment. Past interspecific studies suggest that in general, fishes in large, marine systems produce smaller eggs than those in small, freshwater systems. This study aims to compare egg size intraspecifically among small and large systems. In particular, we focus on populations from the Laurentian Great Lakes, which exhibit similar broadscale physical processes as marine systems, and smaller inland lakes (<1,000 ha), whose ecosystems contain many of the same species. In 2018 and 2019, we collected egg samples from spawning walleye (Sander vitreus) and yellow perch (Perca flavescens) in both inland lake and Great Lake populations. From each female, we recorded total lengths, and measured average diameters of ten eggs. Using ANCOVA models, we compared mean length-adjusted egg diameters intraspecifically among populations of both species. For both walleye and yellow perch, we found that females from inland lakes produced larger mean length-adjusted egg diameters than those of the Great Lakes. This pattern was particularly evident for yellow perch, whereas for walleye the pattern was relatively weak, potentially due to stocking eroding population-specific selection for egg size. These intraspecific patterns are consistent with cross-system interspecific variation in fish egg size.

Down syndrome (DS) is a complex genetic disorder caused by the triplication of human chromosome 21 (Hsa21). The presence of an extra copy of an entire chromosome greatly disrupts the copy number and expression of over 350 protein coding genes. This gene dosage imbalance has far-reaching effects on normal development and aging, leading to cognitive and skeletal defects that emerge earlier in life than the general population.

The present study begins by characterizing skeletal development in young male Ts65Dn mice to test the hypothesis that skeletal defects in male Ts65Dn mice are developmental in nature.Femurs from young mice ranging from postnatal day 12- to 42-days of age (P12-42) were measured and analyzed by microcomputed tomography (μCT). Cortical defects were present generally throughout development, but trabecular defects emerged at P30 and persisted until P42.

The gene Dual-specificity tyrosine-regulated kinase 1a (Dyrk1a) is triplicated in both DS and in Ts65Dn mice and has been implicated as a putative cause of both cognitive and skeletal defects. To test the hypothesis that trisomic Dyrk1a is related to the emergence of trabecular defects at P30, expression of Dyrk1a in the femurs of male Ts65Dn mice was quantified by qPCR. Expression was shown to fluctuate throughout development and overexpression generally aligned with the emergence of trabecular defects at P30.

The growth rate in trabecular measures between male Ts65Dn and euploid littermates was similar between P30 and P42, suggesting a closer look into cellular mechanisms at P42. Assessment of proliferation of BMSCs, differentiation and activity of osteoblasts showed no significant differences between Ts65Dn and euploid cellular activity, suggesting that the cellular microenvironment has a greater influence on cellular activity than genetic background.

These data led to the hypothesis that reduction of Dyrk1a gene expression and pharmacological inhibition of DYRK1A could be executed during a critical period to prevent the emergence of trabecular defects at P30. To tests this hypothesis, doxycycline-induced cre-lox recombination to reduce Dyrk1a gene copy number or the DYRK1A inhibitor CX-4945 began at P21. The results of both genetic and pharmacological interventions suggest that trisomic Dyrk1a does not influence the emergence of trabecular defects up to P30. Instead, data suggest that the critical window for the rescue of trabecular defects lies between P30 and P42.

Preterm birth is the leading cause of newborn mortality, with 15 million babies born premature worldwide every year. Children that do survive early delivery are more likely to develop cognitive abnormalities, motor deficits, heart disease, cerebral palsy, and more. While little is known about the pathophysiology of preterm birth, several pregnancy-related complications are related to preterm birth, namely cervical insufficiency and preeclampsia. In the former, premature cervical remodeling and softening can result in the shortening of the cervix, increasing a woman’s risk of preterm birth; this condition is called cervical insufficiency (CI), which is the inability of the cervix to remain closed as a result of weakened tissues. CI is currently measured by a one-dimensional sonographic cervical length, where < 25 mm indicates shortening. Preeclampsia is a disorder that can be explained through the Page kidney phenomenon: compression of the left renal vein (LRV) causes renal venous outflow obstruction, leading to elevated intrarenal pressure and hypertension. The supine pressor test (SPT) is a diagnostic tool for preeclampsia where a positive test is defined by an increase of 20 mmHg in diastolic blood pressure (BP) when shifting from the left lateral recumbent to the supine position. Due to the intense risk of morbidity and mortality for both the mother and the fetus, the need to monitor BP changes is critical. Currently, there is an unmet clinical need to characterize the hemodynamic and geometric properties of the female reproductive organs throughout gestation. Utilizing ultrasound imaging can increase our knowledge about the 3D anatomy and systemic changes during pregnancy, unravel risk factors, establish preventative methods, and standardize treatment plans. In this thesis research, we developed a murine model to 1) examine the pathophysiology of renal vein stenosis, and 2) investigate the effects of stenosis on various cervical dimensions. Renal vein stenosis was found to greatly impact blood flow velocities, as well as cervical width (p<0.05). LRV and cervical area and height also trend towards significance, and there is negative damage to the left kidney and placentae within the stenosed cohort. We also conducted a human study that showed reduced change in postural BP in patients with higher body mass index (BMI). Systolic and diastolic BP in the supine position was significantly greater than in the lateral position for all BMIs with a baseline increase in BP of approximately 9-14 mmHg. These findings suggest that therapeutic positioning and close monitoring of BP could mitigate the risk of developing related disorders in pregnancy.

This chapter recounts how a few fish species had been domesticated until the mid-twentieth century, describing the classic and “old” domesticates among fishes that are carps and goldfishes and more recently salmonids. Many fishes are being managed and have become effectively domesticated in the sense that their reproductive biology has been changed under human influence in the last few decades. The chapter talks about fish aquaculture that currently involves more than 160 species (Duarte et al. 2007; Bostock et al. 2010), managed for diverse usage goals, including as food and ornament, or for recreation, bio-manipulation, conservation, and research. It covers many fish species now domesticated belong to diverse groups within the evolutionary tree of bony fishes. The zebrafish, Danio rerio, is one of the model organisms of molecular and developmental biology and the populations of this species have gone and are still going through a domestication process.

This chapter explores how attachment theory is increasingly going ‘under the skin’, looking for fundamental biological mechanisms to explain behaviours and consequences. Attachment scholars and researchers have sought new alignments with developments in evolutionary biology and developmental neuroscience. All these domains — despite inconsistent findings, thorny issues relating to extrapolations from animal work, and problems with replication — are purported to provide further support for attachment theory's veracity. In addition, they dangle the tantalising prospects of better targeting of interventions and more efficacious clinical approaches to fixing the effects of disrupted attachments, including some normative and sensitive matters such as the onset of puberty, and what are somewhat euphemistically called ‘reproductive strategies’, often meaning girls having babies too early. This ‘new generation’ of biological reasoning looks to the molecular level to explain health inequalities, with the prevention of adverse childhood experiences on the ‘to do’ list for public health policy makers. This has profound potential implications for child welfare practices.