Masaya Kimishima scite author profile

Growth hormone (GH) transgenesis can be used to manipulate the growth performance of fish and mammals. In this study, homozygous and hemizygous GH-transgenic amago salmon (Oncorhynchus masou ishikawae) derived from a single female exhibited hypoglycemia. Proteomic and signal network analyses using iTRAQ indicated a decreased NAD+/NADH ratio in transgenic fish, indicative of reduced mitochondrial ND1 function and ROS levels. Mitochondrial DNA sequencing revealed that approximately 28% of the deletion mutations in the GH homozygous- and hemizygous-female-derived mitochondrial DNA occurred in ND1. These fish also displayed decreased ROS levels. Our results indicate that GH transgenesis in amago salmon may induce specific deletion mutations that are maternally inherited over generations and alter energy production.

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Predator-induced phenotypic plasticity during early biological evolution and ROS suppression in the brain of Xenopus tropicalis

Mori

Machida

Kudou

et al. 2022

Preprint

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Predator-induced adaptive phenotypic plasticity is essential for evolution. However, Xenopus tropicalis tadpoles do not exhibit distinct phenotypes when exposed to new predation threats. Here, we investigated adaptions within their brain. Principal component analysis using morphological parameters indicated that short-term predation threats (24 hr) altered tadpole morphology unlike the control or 5 day-out treatment (exposure to predation for 5 days and then no exposure for 5 days). Whole-brain ingenuity pathway and metabolome analyses revealed that free radicals, superoxide dismutase, glycogenesis, and pyruvate were elevated after 6 hr of predation pressure. Hemoglobin was also synthesized in the brain, forming oxyhemoglobin in the midbrain and hindbrain to reduce radical production. Furthermore, ATP production through glycolysis was promoted, while β-oxidation and the tricarboxylic acid cycle were downregulated. We also predicted increases in microtubule dynamics, neuronal branching, and neuritogenesis. Therefore, X. tropicalis tadpoles can adapt to predation stress through changes within their central nervous system.

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Novel predator-induced phenotypic plasticity by hemoglobin and physiological changes in the brain of Xenopus tropicalis

et al. 2023

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Organisms adapt to changes in their environment to survive. The emergence of predators is an example of environmental change, and organisms try to change their external phenotypic systems and physiological mechanisms to adapt to such changes. In general, prey exhibit different phenotypes to predators owing to historically long-term prey-predator interactions. However, when presented with a novel predator, the extent and rate of phenotypic plasticity in prey are largely unknown. Therefore, exploring the physiological adaptive response of organisms to novel predators is a crucial topic in physiology and evolutionary biology. Counterintuitively, Xenopus tropicalis tadpoles do not exhibit distinct external phenotypes when exposed to new predation threats. Accordingly, we examined the brains of X. tropicalis tadpoles to understand their response to novel predation pressure in the absence of apparent external morphological adaptations. Principal component analysis of fifteen external morphological parameters showed that each external morphological site varied nonlinearly with predator exposure time. However, the overall percentage change in principal components during the predation threat (24 h) was shown to significantly (p < 0.05) alter tadpole morphology compared with that during control or 5-day out treatment (5 days of exposure to predation followed by 5 days of no exposure). However, the adaptive strategy of the altered sites was unknown because the changes were not specific to a particular site but were rather nonlinear in various sites. Therefore, RNA-seq, metabolomic, Ingenuity Pathway Analysis, and Kyoto Encyclopedia of Genes and Genomes analyses were performed on the entire brain to investigate physiological changes in the brain, finding that glycolysis-driven ATP production was enhanced and ß-oxidation and the tricarboxylic acid cycle were downregulated in response to predation stress. Superoxide dismutase was upregulated after 6 h of exposure to new predation pressure, and radical production was reduced. Hemoglobin was also increased in the brain, forming oxyhemoglobin, which is known to scavenge hydroxyl radicals in the midbrain and hindbrain. These suggest that X. tropicalis tadpoles do not develop external morphological adaptations that are positively correlated with predation pressure, such as tail elongation, in response to novel predators; however, they improve their brain functionality when exposed to a novel predator.

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