C.-C. Tai scite author profile

C.-C. Tai

3Publications

53Citation Statements Received

191Citation Statements Given

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125

181

Affiliations

National Taiwan University, Institute of Atomic and Molecular Sciences, Academia Sinica

Publications

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Histone deacetylase inhibitor treatment restores memory‐related gene expression and learning ability in neonicotinoid‐treated Apis mellifera

Tang

et al. 2018

Insect Molecular Biology

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Apis mellifera plays crucial roles in maintaining the balance of global ecosystems and stability of agricultural systems by helping pollination of flowering plants, including many crops. In recent years, this balance has been disrupted greatly by some pesticides, which results in great losses of honeybees worldwide. Previous studies have found that pesticide-caused memory loss might be one of the major reasons for colony loss. Histone deacetylase inhibitors (HDACis) are chemical compounds that inhibit the activity of histone deacetylases and are known to cause hyperacetylation of histone cores and influence gene expression. In our study, the HDACi sodium butyrate was applied to honeybees as a dietary supplement. The effect of sodium butyrate on the expression profiles of memory-related genes was analysed by quantitative reverse transcription PCR. The results revealed that this HDACi had up-regulation effects on most of the memory-related genes in bees, even in bees treated with imidacloprid. In addition, using the proboscis extension reflex to evaluate olfactory learning in bees, we found that this HDACi boosted the memory formation of bees after impairment owing to imidacloprid exposure. This study investigated the association between gene expression and memory formation from an epigenetic perspective. Additionally, we further demonstrate the possibility of enhancing bee learning using HDACis and provide initial data for future research.

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Adenosine Receptor Modulates Permissiveness of Baculovirus (Budded Virus) Infection via Regulation of Energy Metabolism in Bombyx mori

et al. 2020

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Although the modulation of host physiology has been interpreted as an essential process supporting baculovirus propagation, the requirement of energy supply for host antivirus reactions could not be ruled out. Our present study showed that metabolic induction upon AcMNPV (budded virus) infection of Bombyx mori stimulated virus clearance and production of the antivirus protein, gloverin. In addition, we demonstrated that adenosine receptor signaling (AdoR) played an important role in regulating such metabolic reprogramming upon baculovirus infection. By using a second lepidopteran model, Spodoptera frugiperda Sf-21 cells, we demonstrated that the glycolytic induction regulated by adenosine signaling was a conservative mechanism modulating the permissiveness of baculovirus infection. Another interesting finding in our present study is that both BmNPV and AcMNPV infection cause metabolic activation, but it appears that BmNPV infection moderates the level of ATP production, which is in contrast to a dramatic increase upon AcMNPV infection. We identified potential AdoR miRNAs induced by BmNPV infection and concluded that BmNPV may attempt to minimize metabolic activation by suppressing adenosine signaling and further decreasing the host's anti-baculovirus response. Our present study shows that activation of energy synthesis by adenosine signaling upon baculovirus infection is a host physiological response that is essential for supporting the innate immune response against infection.

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Recombination Reactions of Atomic Chlorine in Compressed Gases. 1. Chemiluminescence Spectra of Chlorine Molecules with Argon Pressure Up to 170 bar

et al. 1996

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The gas-phase chemiluminescence spectra of chlorine atom recombination reactions in argon with pressures up to 170 bar were recorded by the laser photolysis/chemiluminescence detection scheme. With the spectroscopic data available in the literature and the monochromator functions determined experimentally and by assuming that the pressure line broadenings and frequency shifts follow the conventional Lorentzian form, for the first time the chemiluminescence spectra were quantitatively decomposed into the emissions of the B 3 Π(0 u + ) f X 1 Σ g + and A 3 Π(1 u ) f X 1 Σ g + transitions. The relative luminescence weights of these two emission electronic states, the vibrational temperatures, the pressure line broadenings, and frequency shifts were obtained. Their implications on the mechanisms of the chlorine atom recombination reactions and the interaction strength between the chlorine molecule and argon atom were discussed.

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C.-C. Tai

Histone deacetylase inhibitor treatment restores memory‐related gene expression and learning ability in neonicotinoid‐treated Apis mellifera

Adenosine Receptor Modulates Permissiveness of Baculovirus (Budded Virus) Infection via Regulation of Energy Metabolism in Bombyx mori

Recombination Reactions of Atomic Chlorine in Compressed Gases. 1. Chemiluminescence Spectra of Chlorine Molecules with Argon Pressure Up to 170 bar

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