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Molecular and Physiological Mechanisms of Toxin Resistance in Toad-Eating SnakesMohammadi, Shabnam 01 May 2017 (has links)
Many plants and animals are defended by toxic compounds, and circumvention of those defenses often has involved the evolution of elaborate mechanisms for tolerance or resistance of the toxins. Toads synthesize potent cardiotonic steroids known as bufadienolides (BDs) from cholesterol and store those toxins in high concentrations in their cutaneous glands. Those toxins protect toads from the majority of predators, including most snakes that readily consume other species of frogs. BDs exert their effect by inhibiting ion transport by the Na+/K+-ATPase (NKA). This ubiquitous transmembrane enzyme consists of a catalytic alpha-subunit, which carries out the enzyme's functions, and a glycoprotein beta-subunit, which provides structural stability. Inhibition of the NKA causes highly elevated intracellular Ca2+ levels and results in often lethal increased cardiac contraction strength. Molecular resistance to bufadienolides in snakes is conferred by mutations in the alpha-subunit of the Na+/K+-ATPase. I have found that these mutations are more prevalent in snakes than previously suggested, and that many genetically resistant species do not feed on toads. This suggests that possession of the mutations alone does not carry substantial negative consequences, and that feeding on toads may have been an ancestral habit in some groups of snakes. I have further found evidence of tissue-specific variation in resistance to bufadienolides, and gene expression investigations revealed that the bufadienolide resistance-conferring mutations are not expressed equally among different organs. Variation in resistance among different tissues indicates that possession of the mutations does not protect all cells equally. Finally, by testing the physiological responses of resistant snakes to exposure to cardiotonic steroid, I have found that feeding on toads incurs negative consequences and that toad-specialized resistant snakes respond differently from nontoad-specialized resistant snakes. The presence of physiological consequences of toxin exposure may explain why feeding on toads has been lost in some lineages of snakes that retain resistance-conferring mutations. In summary, these findings indicate that genetic resistance of the Na+/K+-ATPase is necessary in order for snakes to survive acute toxicity of bufadienolides, but it is not sufficient to explain fully the physiological mechanisms involved in dealing with chronic exposure to the toxins.
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Adaptive evolution, sex-linkage, and gene conversion in the voltage-gated sodium channels of toxic newts and their snake predatorsGendreau, Kerry 27 May 2022 (has links)
Understanding how genetic changes ultimately affect morphology and physiology is essential for understanding and predicting how organisms will adapt to environmental changes. Although most traits are complex and involve the interplay of many different genetic loci, some exceptions exist. These include the convergent evolution of tetrodotoxin resistance in snakes, which has a simple genetic basis and can be used as a model system to investigate the genetic basis of adaptive evolution. Tetrodotoxin is a potent neurotoxin used as a chemical defense by various animals, including toxic newts. Snakes have evolved resistance through mutations in voltage-gated sodium channels, the protein targets of tetrodotoxin, sparking an evolutionary arms race between predator and prey. In this dissertation, I describe how genomic rearrangements have led to sex-linkage of four of the voltage-gated sodium channel genes in snakes and compare allele frequencies across populations and sexes to make inferences about how sex linkage has influenced the evolution of resistance in garter snakes. By measuring gene expression in different snake tissues, I show that three of these sex-linked sodium channel genes are dosage compensated in embryos, adult muscle, and adult brain. In contrast, two channels show sexual dimorphism in their expression levels in the heart, which may indicate differences in dosage compensation among tissues. I then use comparative genomics to track the evolutionary history of tetrodotoxin resistance across all nine sodium channel genes in squamate reptiles and show how historical changes have paved the way for full-body resistance in certain snakes. Finally, I use targeted sequence capture to obtain the sodium channel sequences of salamanders and show evidence that tetrodotoxin self-resistance in toxic newts was likely accelerated through gene conversion between resistant and non-resistant sodium channel paralogs. Together, these results illustrate parallelism in evolutionary mechanisms and processes contributing to the appearance of an extreme and complex trait that arose independently in two distinct taxa separated by hundreds of millions of years. / Doctor of Philosophy / Western North America is the site of an ongoing battle between highly toxic species of salamanders (toxic newts) and their garter snake predators. In certain regions, garter snakes have countered newt defenses by evolving resistance to their toxins, and the newts have become more toxic in response. This interaction has been the focus of scientists for decades because it teaches us about the ways in which animals can respond to changes in their environment. In living organisms, DNA is used a blueprint to determine the ultimate traits that are expressed (e.g., whether an organism will have five fingers or four, or whether it will be resistant or sensitive to a toxin). By comparing DNA sequences of different life forms, we are beginning to understand the rules that determine how these blueprints are read and how they can change over time. Because life is built upon the same basic building blocks (DNA, mRNA, and proteins), information about this snake-newt system can be used to understand the way that other systems, such as humans and pathogens, might interact. In my dissertation, I compare DNA sequences from snakes and lizards to identify the history of changes leading to the extreme toxin resistance in the garter snakes. I show that toxin resistance began hundreds of millions of years ago, with all lizards having a low baseline level of resistance, and that resistance built up slowly in the lineages leading to garter snakes. I also show that because of DNA rearrangements, female snakes have fewer copies of some of the genes involved in resistance, and this may have led to differences among the sexes. Lastly, I compare DNA sequences among salamanders, revealing a similar pattern to that in snakes and lizards. Specifically, newts have evolved self-resistance to their own toxin, and this has happened gradually over hundreds of millions of years, with all salamanders having some toxin resistance. I also show that an unusual process occurred within the DNA of toxic newts, resulting in a rapid change from toxin sensitivity to toxin resistance in some genes. Taken together, this work helps advance our understanding of the processes and limitations that determine how organisms can function and change over time.
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