Modulation of plasma protein expression in bullfrog (Rana catesbeiana) tadpoles during seasonal acclimatization and thermal acclimation.

Biological activities in ectothermic vertebrates depend to a great extent on ambient temperature. Adapting their biological systems to annual or short-term alterations in temperature may play an important role in thermal resistance or overwintering survival. Using SDS-PAGE and western blot, we examined plasma proteins in bullfrog (Rana catesbeiana) tadpoles that were seasonally acclimatized (winter vs. summer) or thermally acclimated (4 °C vs. 21 °C) and identified two season-responsive proteins. The first, transthyretin (TTR), is a plasma thyroid hormone distributor protein that was abundant in summer, and the second is a protein containing C-type lectin-like domain (CTLD) that was abundant in winter and cold acclimation of 4 weeks. Sequence analysis revealed that the C-terminal carbohydrate recognition domain of this CTLD protein (termed collectin X) was highly similar to those of the collectin family members, which participate in complement activation of the innate immune system; however, it lacked most of collagen-like domain. Among the hepatic genes involved in the thyroid system, ttr and dio3 were up-regulated, whereas thra and thrb were down-regulated, in summer acclimatization or warm acclimation. In contrast, the collectin X gene (colectx), as well as colect10 and colect11 in the collectin family involved in the innate immune system, were down-regulated during warm acclimation, although fcn2 in the ficolin family was up-regulated during summer acclimatization and warm acclimation. These findings indicate that seasonal acclimatization and thermal acclimation differentially affect some components of the thyroid and innate immune systems at protein and transcript levels.

Recovery of the histamine H3 receptor activity lost in yeast cells through error-prone PCR and in vivo selection.

G protein-coupled receptors (GPCRs) are the largest protein family in humans and are important drug targets. Yeast, especially Saccharomyces cerevisiae, is a useful host for modifying the function and stability of GPCRs through protein engineering, which is advantageous for mammalian cells. When GPCRs are expressed in yeast, their function is often impaired. In this study, we performed random mutagenesis using error-prone PCR and then an in vivo screening to obtain mutants that recovered the activity of the human histamine H3 receptor (H3R), which loses its signaling function when expressed in yeast. Four mutations with recovered activity were identified after screening. Three of the mutations were identified near the DRY and NPxxY motifs of H3R, which are important for activation and are commonly found in class A GPCRs. The mutants responded exclusively to the yeast YB1 strain harboring Gi-chimera proteins, showing retention of G protein specificity. Analysis of one of the mutants with recovered activity, C415R, revealed that it maintained its ligand-binding characteristics. The strategy used in this study may enable the recovery of the activity of other GPCRs that do not function in S. cerevisiae and may be useful in creating GPCRs mutants stabilized in their active conformations.

Adult male Xenopus laevis can tolerate months of fasting by catabolizing carbohydrates and lipids.

The African clawed frog, Xenopus laevis, has been reported to tolerate long-term fasting without dormancy. However, the strategies for energy acquisition during fasting are unclear in this species. We performed 3- and 7-month fasting experiments to investigate how the metabolism of male X. laevis changes during long-term fasting. We found that the levels of several serum biochemical parameters, such as glucose, triglycerides, and free fatty acids, as well as liver glycogen were reduced after 3 months of fasting, whereas after 7 months of fasting, triglyceride levels were reduced, and fat body wet weight was lower than that of fed group indicating the onset of lipid catabolism. In addition, transcript levels of gluconeogenic genes, such as pck1, pck2, g6pc1.1, and g6pc1.2, were increased in the livers of animals fasted for 3 months, suggesting upregulation of gluconeogenesis. Our results raise the possibility that male X. laevis can tolerate much longer fasting than previously reported by utilizing several energy storage molecules. Further investigation of the effects of prolonged fasting on the metabolic switches from carbohydrates to lipids or amino acids in X. laevis is required.