Kouki Tadai scite author profile

Kouki Tadai

3Publications

16Citation Statements Received

53Citation Statements Given

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Affiliations

Institute for Molecular Science, Tokyo Metropolitan University, Advanced Neural Dynamics (United States)

Publications

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Marginally excessive iron loading transiently blocks mucosal iron uptake in iron-deficient rats

Shinoda

Yoshizawa

Nozaki

et al. 2014

American Journal of Physiology-Gastrointestinal and Liver Physi

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Regular “mucosal block” is characterized by decreased uptake of a normal iron load 3–72 h after the administration of excess iron (generally 10 mg) to iron-deficient animals. We found that short-acting mucosal block could be induced by much lower iron concentration and much shorter induction time than previously reported, without affecting levels of gene expression. A rapid endocytic mechanism was reported to decrease intestinal iron absorption after a high iron load, but the activating iron load and the time to decreased absorption were undetermined. We assessed the effects of 30–2,000 μg iron load on iron uptake in the duodenal loop of iron-deficient and iron-sufficient rats under anesthesia. One hour later, mucosal cellular iron uptake in iron-deficient rats administered 30 μg iron was 76.1%, decreasing 25% to 50.7% in rats administered 2,000 μg iron. In contrast, iron uptake by iron-sufficient rats was 63% (range 60.3–65.5%) regardless of iron load. Duodenal mucosal iron concentration was significantly lower in iron-deficient than in iron-sufficient rats. Iron levels in portal blood were consistently higher in iron-deficient rats regardless of iron load, in contrast to the decreased iron uptake on the luminal side. Iron loading blocked mucosal uptake of marginally excess iron (1,000 μg), with a greater effect at 15 min than at 30 min. The rapid induction of short-acting mucosal block only in iron-deficient rats suggests DMT1 internalization.

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Rapid Regulation of Intestinal Divalent Metal (Cation) Transporter 1 (DMT1/DCT1) and Ferritin mRNA Expression in Response to Excess Iron Loading in Iron-Deficient Rats

Arita

Tadai

Shinoda

2010

Bioscience, Biotechnology, and Biochemistry

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Interaction of receptor type of protein tyrosine phosphatase sigma (RPTPσ) with a glycosaminoglycan library

Tadai

Shioiri

Tsuchimoto

et al. 2018

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Receptor type of protein tyrosine phosphatase sigma (RPTPσ) functions as a glycosaminoglycan (GAG) receptor of neuronal cells in both the central and peripheral nervous systems. Both chondroitin sulphate (CS) and heparan sulphate (HS) are important constituents of GAG ligands for RPTPσ, although they have opposite effects on neuronal cells. CS inhibits neurite outgrowth and neural regeneration through RPTPσ, whereas HS enhances them. We prepared recombinant RPTPσ N-terminal fragment containing the GAG binding site and various types of biotin-conjugated GAG (CS and HS) with chemical modification and chemo-enzymatic synthesis. Then interaction of the RPTPσ N-terminal fragment was analysed using GAG-biotin immobilized on streptavidin sensor chips by surface plasmon resonance. Interaction of RPTPσ with the CS library was highly correlated to the degree of disulphated disaccharide E unit, which had two sulphate groups at C-4 and C-6 positions of the N-acetylgalactosamine residue (CSE). The optimum molecular mass of CSE was suggested to be approximately 10 kDa. Heparin showed higher affinity to RPTPσ than the CS library. Our GAG library will not only contribute to the fields of carbohydrate science and cell biology, but also provide medical application to regulate neural regeneration.

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Kouki Tadai

Marginally excessive iron loading transiently blocks mucosal iron uptake in iron-deficient rats

Rapid Regulation of Intestinal Divalent Metal (Cation) Transporter 1 (DMT1/DCT1) and Ferritin mRNA Expression in Response to Excess Iron Loading in Iron-Deficient Rats

Interaction of receptor type of protein tyrosine phosphatase sigma (RPTPσ) with a glycosaminoglycan library

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