The Effects of Hypoxia and Temperature on Developing Embryos of the Annual Killifish Austrofundulus limnaeus

Anderson, Skye N.

01 January 2012

Little is known about the physiology or biochemistry of hypoxia (reduced levels of oxygen) tolerance during development in vertebrate embryos. In most species, relatively brief bouts of severe hypoxia are lethal or teratogenic. An exception to such hypoxia intolerance is the annual killifish Austrofundulus limnaeus, in which populations persist in hypoxic environments. This species inhabits seasonal ponds in Venezuela, surviving through the dry season in the form of diapausing embryos. Embedded in the pond sediment, embryos of A. limnaeus are routinely exposed to hypoxia and anoxia (lack of oxygen) as part of their normal development. Here, we exposed embryos to various levels of PO2 (21.2, 15.6, 10.8, 8.4, 6.1, 3.6, and 2.2 kPa) at two different temperatures (25°C and 30°C) to study the effects on developmental rate and heart rate. We also measured enzyme activity and quantified DNA content of individual embryos to compare differences among the varying levels of hypoxia and temperature. Hypoxia caused a significant decline in developmental rate and caused a stage-specific decline in heart rate. Higher temperature caused an increase in the developmental rate for those embryos incubated at PO2 of 6.1 kPa and greater. Temperature had a negative effect by hindering development below a PO2 of 6.1 kPa. Total embryonic DNA content was reduced at low partial pressures (15.6, 10.8, 8.4, 6.1, 3.6, and 2.2 kPa) of oxygen. Citrate synthase, lactate dehydrogenase, and phosphoenolpyruvate carboxykinase were all down-regulated indicating a complete lack of enzymatic metabolic compensation to combat reduced oxygen levels.

Killifishes -- Embryos -- Development

Anoxemia -- Pathophysiology

Aquaculture and Fisheries

Developmental Biology

Other Physiology

Transcriptomic Regulation of Alternative Phenotypic Trajectories in Embryos of the Annual Killifish <i>Austrofundulus limnaeus</i>

Romney, Amie L.

30 November 2017

The Annual Killifish, Austrofundulus limnaeus, survives the seasonal drying of their pond habitat in the form of embryos entering diapause midway through development. The diapause trajectory is one of two developmental phenotypes. Alternatively, individuals can "escape" entry into diapause and develop continuously until hatching. The alternative phenotypes of A. limnaeus are a form of developmental plasticity that provides this species with a physiological adaption for surviving stressful environments. The developmental trajectory of an embryo is not distinguishable morphologically upon fertilization and phenotype is believed to be influenced by maternal provisioning within the egg based on observations of offspring phenotype production. However, incubation temperature may override any such maternal pattern suggesting an environmental influence on the regulation of developmental trajectory. We hypothesize that maternally packaged gene products coordinate the cellular events prior to the maternal-to-zygotic transition (MTZ) that determine developmental trajectory in embryos of A. limnaeus. In addition, we propose that environmentally responsive gene expression after the MTZ can sustain or override any such maternal provisioning. Using high-throughput RNA-sequencing, we have generated transcriptomic profiles of protein-coding messenger RNA and noncoding RNA during development in A. limnaeus. Embryos destined for either the diapause or escape phenotypes display unique expression profiles immediately upon fertilization that support hormone synthesis, well before the stage when phenotypes are morphologically distinct. At stages when the trajectories diverge from one another, differential expression of the vitamin D receptor signaling pathway suggests that vitamin D signaling may be a key regulator of developmental phenotype in this species. These data provide a critical link between maternal and environmental influences on the genetic regulation of phenotypic plasticity. These results will not only impact our understanding of the genetic mechanisms that regulate entrance into diapause, but also provide insight into the epigenetic regulation of gene expression and development. Uncovering genetic mechanisms in a system exhibiting alternative developmental trajectories will elucidate the role of maternal packaging in regulating developmental decisions, and in sustaining metabolic depression during diapause.

Killifishes -- Embryos -- Development

Gene expression

Diapause

Developmental genetics

Biology

Genetics and Genomics

Developmental Mechanisms that Support Genome Stability and Embryonic Survival in Stress-tolerant Embryos of the Annual Killifish <i>Austrofundulus limnaeus</i>

Wagner, Josiah Tad

18 September 2015

In order to complete their life cycles, vertebrates require oxygen and water. However, environments are not always forgiving when it comes to constantly providing these basic needs for vertebrate life. The annual killifish Austrofundulus limnaeus is possibly the most well described extremophile vertebrate and its embryos have been shown to tolerate extremes in oxygen, salinity, and water availability. This phenotype is likely a result of the annual killifish life history, which includes periods of temporary habitat desiccation and oxygen deprivation, and requires the production of stress-tolerant embryos that depress metabolism in a state of suspended animation, known as diapause. Over the past several decades, the basic morphology and physiology of annual killifish development has become better characterized. However, there are still basic cellular processes that remain to be described in annual killifish such as A. limnaeus. Specifically, changes in DNA structure, expression, and copy number are known to have profound impacts on the phenotype and survival of an organism. Little is known as to how A. limnaeus maintains genome integrity during cell stress, nor how the A. limnaeus nuclear and mitochondrial genomes may have evolved under the unpredictable conditions in which A. limnaeus thrive. Early annual killifish embryonic development is also characterized by a complete dispersion and subsequent reaggregation of embryonic blastomeres prior to formation of the embryonic axis. This unusual period of early development may provide a functional adaptation that allows annual killifish embryos to survive these extreme conditions. The overall goals of this project were to (1) characterize the ability of A. limnaeus to tolerate and repair DNA damage through enzymatic and developmental mechanisms, (2) to determine possible consequences of mitochondrial DNA sequence and copy number on the metabolism of A. limnaeus, and (3) to establish a draft genome of A. limnaeus for future comparative genome studies. The results of this project show that embryos of A. limnaeus have an impressive ability to survive and reverse high doses of DNA damage induced by ultraviolet-C (UV-C) radiation, especially when allowed to recover under photoreactivating light. Surprisingly, embryos that survived irradiation during blastomere dispersion phases were able to develop normally. Characterization of gene expression during embryonic development for genes important for axis formation and cellular differentiation suggests that A. limnaeus embryos may delay axis formation until several days after epiboly is complete, thus allowing time for cells that become damaged to be replaced by surrounding pluripotent cells. This outcome would represent first case of a developmental buffering stage in a vertebrate. A. limnaeus embryos are also unique in their mitochondrial response to anoxia. Whereas in other species the amount of mitochondrial DNA (mtDNA) copy number fluctuates following extremes in oxygen availability, A. limnaeus embryonic mtDNA remains stable. Additionally, characterization of the fully sequenced A. limnaeus mitochondrial genome reveals possible evolutionary adaptations that may have facilitated dormancy and anoxia tolerance when compared to other species within the Order Cyprinodontiformes. The final chapter of this project characterizes the draft genome of A. limnaeus and I provide evidence suggesting that epigenetic DNA methylation that may be involved in regulating diapause.

Killifishes -- Embryos -- Development

Diapause

Gene expression

Animal Sciences

Biology

Genetics and Genomics