271 results on '"Koyanagi, Satoru"'
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2. Implications of biological clocks in pharmacology and pharmacokinetics of antitumor drugs
3. Modulation of cell physiology by bispecific nanobodies enabling changes in the intracellular localization of organelle proteins
4. Chronopharmacology of immune-related diseases
5. RNA editing enzyme ADAR1 controls miR-381-3p-mediated expression of multidrug resistance protein MRP4 via regulation of circRNA in human renal cells
6. Epigenetic repression of de novo cysteine synthetases induces intra-cellular accumulation of cysteine in hepatocarcinoma by up-regulating the cystine uptake transporter xCT.
7. Circadian rhythms in CYP2A5 expression underlie the time-dependent effect of tegafur on breast cancer
8. Prostaglandin F2α Affects the Cycle of Clock Gene Expression and Mouse Behavior
9. Suppression of neuropathic pain in the circadian clock–deficient Per2m/m mice involves up-regulation of endocannabinoid system
10. Time-dependent differences in vancomycin sensitivity of macrophages underlie vancomycin-induced acute kidney injury
11. Alteration of circadian machinery in monocytes underlies chronic kidney disease-associated cardiac inflammation and fibrosis
12. RNA editing enzyme ADAR2 regulates P-glycoprotein expression in murine breast cancer cells through the circRNA-miRNA pathway
13. Optimizing the dosing schedule of l-asparaginase improves its anti-tumor activity in breast tumor-bearing mice
14. Contribution of the clock gene DEC2 to VEGF mRNA upregulation by modulation of HIF1α protein levels in hypoxic MIO-M1 cells, a human cell line of retinal glial (Müller) cells
15. Inhibition of Tumor-Derived C-C Motif Chemokine Ligand 2 Expression Attenuates Tactile Allodynia in NCTC 2472 Fibrosarcoma-Inoculated Mice
16. The scaffold protein PDZK1 governs diurnal localization of CNT2 on the plasma membrane in mouse intestinal epithelial cells
17. Senescence-induced alteration of circadian phagocytic activity of retinal pigment epithelium cell line ARPE-19
18. Dietary supplementation with essence of chicken enhances daily oscillations in plasma glucocorticoid levels and behavioral adaptation to the phase-shifted environmental light–dark cycle in mice
19. Diurnal expression of MRP4 in bone marrow cells underlies the dosing-time dependent changes in the oxaliplatin-induced myelotoxicity
20. Supplementary Figure from Diurnal Expression of PD-1 on Tumor-Associated Macrophages Underlies the Dosing Time-Dependent Antitumor Effects of the PD-1/PD-L1 Inhibitor BMS-1 in B16/BL6 Melanoma-Bearing Mice
21. Supplementary Data from Diurnal Expression of PD-1 on Tumor-Associated Macrophages Underlies the Dosing Time-Dependent Antitumor Effects of the PD-1/PD-L1 Inhibitor BMS-1 in B16/BL6 Melanoma-Bearing Mice
22. Data from Diurnal Expression of PD-1 on Tumor-Associated Macrophages Underlies the Dosing Time-Dependent Antitumor Effects of the PD-1/PD-L1 Inhibitor BMS-1 in B16/BL6 Melanoma-Bearing Mice
23. Fig. S11-S13 from Optimized Dosing Schedule Based on Circadian Dynamics of Mouse Breast Cancer Stem Cells Improves the Antitumor Effects of Aldehyde Dehydrogenase Inhibitor
24. Table S3 from Optimized Dosing Schedule Based on Circadian Dynamics of Mouse Breast Cancer Stem Cells Improves the Antitumor Effects of Aldehyde Dehydrogenase Inhibitor
25. Data from Optimized Dosing Schedule Based on Circadian Dynamics of Mouse Breast Cancer Stem Cells Improves the Antitumor Effects of Aldehyde Dehydrogenase Inhibitor
26. Supplementary methods from Optimized Dosing Schedule Based on Circadian Dynamics of Mouse Breast Cancer Stem Cells Improves the Antitumor Effects of Aldehyde Dehydrogenase Inhibitor
27. Supplementary Data 6 from Circadian Regulation of mTOR by the Ubiquitin Pathway in Renal Cell Carcinoma
28. Supplementary Table 3 from Stress-Regulated Transcription Factor ATF4 Promotes Neoplastic Transformation by Suppressing Expression of the INK4a/ARF Cell Senescence Factors
29. Supplementary Data 1 from Circadian Regulation of mTOR by the Ubiquitin Pathway in Renal Cell Carcinoma
30. Data from Circadian Rhythm of Transferrin Receptor 1 Gene Expression Controlled by c-Myc in Colon Cancer–Bearing Mice
31. Supplementary Data 4 from Circadian Regulation of mTOR by the Ubiquitin Pathway in Renal Cell Carcinoma
32. Supplementary Data 3 from Circadian Regulation of mTOR by the Ubiquitin Pathway in Renal Cell Carcinoma
33. Supplementary Table 1 from Stress-Regulated Transcription Factor ATF4 Promotes Neoplastic Transformation by Suppressing Expression of the INK4a/ARF Cell Senescence Factors
34. Supplementary Figure 4 from Circadian Rhythm of Transferrin Receptor 1 Gene Expression Controlled by c-Myc in Colon Cancer–Bearing Mice
35. Supplementary Data 5 from Circadian Regulation of mTOR by the Ubiquitin Pathway in Renal Cell Carcinoma
36. Supplementary Figure 1 from Circadian Rhythm of Transferrin Receptor 1 Gene Expression Controlled by c-Myc in Colon Cancer–Bearing Mice
37. Supplementary Figure 1 from Rhythmic Control of the ARF-MDM2 Pathway by ATF4 Underlies Circadian Accumulation of p53 in Malignant Cells
38. Supplementary Figures 1-5 from Stress-Regulated Transcription Factor ATF4 Promotes Neoplastic Transformation by Suppressing Expression of the INK4a/ARF Cell Senescence Factors
39. Supplementary Figure 3 from Circadian Rhythm of Transferrin Receptor 1 Gene Expression Controlled by c-Myc in Colon Cancer–Bearing Mice
40. Supplementary Figure 2 from Rhythmic Control of the ARF-MDM2 Pathway by ATF4 Underlies Circadian Accumulation of p53 in Malignant Cells
41. Data from Circadian Regulation of mTOR by the Ubiquitin Pathway in Renal Cell Carcinoma
42. Supplementary Figure 5 from Circadian Rhythm of Transferrin Receptor 1 Gene Expression Controlled by c-Myc in Colon Cancer–Bearing Mice
43. Supplementary Table 2 from Stress-Regulated Transcription Factor ATF4 Promotes Neoplastic Transformation by Suppressing Expression of the INK4a/ARF Cell Senescence Factors
44. Data from Stress-Regulated Transcription Factor ATF4 Promotes Neoplastic Transformation by Suppressing Expression of the INK4a/ARF Cell Senescence Factors
45. Supplementary Methods, Figure Legends from Rhythmic Control of the ARF-MDM2 Pathway by ATF4 Underlies Circadian Accumulation of p53 in Malignant Cells
46. Data from Rhythmic Control of the ARF-MDM2 Pathway by ATF4 Underlies Circadian Accumulation of p53 in Malignant Cells
47. Supplementary Figure 3 from Rhythmic Control of the ARF-MDM2 Pathway by ATF4 Underlies Circadian Accumulation of p53 in Malignant Cells
48. Supplementary Figure 4 from Rhythmic Control of the ARF-MDM2 Pathway by ATF4 Underlies Circadian Accumulation of p53 in Malignant Cells
49. Supplementary Figure 2 from Circadian Rhythm of Transferrin Receptor 1 Gene Expression Controlled by c-Myc in Colon Cancer–Bearing Mice
50. Supplementary Data 2 from Circadian Regulation of mTOR by the Ubiquitin Pathway in Renal Cell Carcinoma
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