Transgenerational Responses to Environmental Stressors in Vertebrates: From Organisms to Molecules

Martinez Bautista, Naim

12 1900

Genomic modifications occur slowly across generations, whereas short-term epigenetic transgenerational inheritance of adaptive phenotypes may be immediately beneficial to large numbers of individuals, acting as a bridge for survival when adverse environments occur. In this study we used dietary exposure to crude oil as an example of an environmental stressor to assess its effects from the molecular to the organismal levels in piscine and avian animal models. In addition, we assessed the role of the parental exposures on their offspring F1 generation. The research developed in this dissertation has contributed to several areas of investigation including molecular biology, animal physiology, and evolutionary biology. The quantitative information from these studies may be utilized to supplement information regarding the proximate and ultimate effects of environmental stressors on fish and bird populations. Furthermore, this information may be used as additional support for understanding the conservation of the responses from the molecular to the whole organismal levels across the vertebrate taxa, as well as their implications for population survival and maintenance. Additionally, the zebrafish (Danio rerio), the Siamese fighting fish (Betta splendens) and the king quail (Coturnix chinensis) have proven to be excellent models to start building a strong basis for understanding the effects of environmental stressors and transgenerational epigenetic phenomena using a multi-level approach. Furthermore, as more raw data and information is discovered, the concatenation of development, organismal variation, epigenetics inheritance, natural selection, speciation and evolution is being slowly decrypted.

Transgenerational epigenetics

Evolution

Phenotypic pladticity

Developmental physiology

Crude oil

Animal models

Biology, Physiology

Biology, Animal Physiology

Phenotypic Morphological Plasticity Induced by Environmental Salt Stress in the Brine Shrimp, Artemia franciscana

Jones, Shaun Gray

12 1900

Phenotypic plasticity is the ability of an organism to express different phenotypes in response to biotic or abiotic environmental cues. The ability of an organism to make changes during development to adjust to changes in its environment is a key to survival. Sexually reproducing organisms that have short life cycles and that are easy to raise in the laboratory are more conducive for developmental phenotypic plasticity. Considerable research has already been carried out on the brine shrimp, Artemia franciscana, regarding its morphology due to changing salinities. There is, however, little research considering subsequent generations and how there morphology might be affected by parental experiences. This study has examined: 1) the morphological effects of different rearing regimes of different salinity levels, and 2) the epigenetic transgenerational transfer of these morphological traits in A. franciscana. Measurements included rate of growth (as measured by instar), body size, body length, and other morphological traits. A gradual increase to more hyperosmotic conditions during development produced brine shrimp that were larger in size and also more developmentally advanced. Salinity stress experienced by adults had increased the growth rate in the F1 offspring of A. franciscana. Collectively, these data indicate that Artemia franciscana is a tractable model for investigating phenotypic plasticity. These findings have added to the ever-growing field of developmental phenotypic plasticity while also providing more information on the natural history and adaptive abilities of A. franciscana.

Artemia francisana

brine shrimp

developmental physiology

epigenetics

salinity

phenotypic plasticity

environment

stressor

morphology

Artemia -- Effect of salt on.

Artemia -- Effect of stress on.

Artemia -- Morphology.

Phenotypic plasticity.

The regulation of Msx genes by Wnt and BMP signalling during stem cell development /

Hussein, Samer M.

January 2008

No description available.

Stem Cells -- physiology.

Homeodomain Proteins -- physiology.

Wnt Proteins -- physiology.

Neural Crest -- physiology.

Signal Transduction -- physiology.