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1. CtIP Regulates Mitotic Spindle Assembly by Modulating the TPX2-Aurora A Signaling Axis

2. Development of an Anti-canine PD-L1 Antibody and Caninized PD-L1 Mouse Model as Translational Research Tools for the Study of Immunotherapy in Humans

3. Abstract P3-07-24: Role of tumor cell-derived lactic acid in the PD-1/PD-L1 blockade resistant tumor

4. FIGURE 4 from Development of an Anti-canine PD-L1 Antibody and Caninized PD-L1 Mouse Model as Translational Research Tools for the Study of Immunotherapy in Humans

5. FIGURE 1 from Development of an Anti-canine PD-L1 Antibody and Caninized PD-L1 Mouse Model as Translational Research Tools for the Study of Immunotherapy in Humans

6. Data from Development of an Anti-canine PD-L1 Antibody and Caninized PD-L1 Mouse Model as Translational Research Tools for the Study of Immunotherapy in Humans

7. FIGURE 5 from Development of an Anti-canine PD-L1 Antibody and Caninized PD-L1 Mouse Model as Translational Research Tools for the Study of Immunotherapy in Humans

8. FIGURE 2 from Development of an Anti-canine PD-L1 Antibody and Caninized PD-L1 Mouse Model as Translational Research Tools for the Study of Immunotherapy in Humans

9. FIGURE 3 from Development of an Anti-canine PD-L1 Antibody and Caninized PD-L1 Mouse Model as Translational Research Tools for the Study of Immunotherapy in Humans

10. FIGURE 6 from Development of an Anti-canine PD-L1 Antibody and Caninized PD-L1 Mouse Model as Translational Research Tools for the Study of Immunotherapy in Humans

11. TABLE 1 from Development of an Anti-canine PD-L1 Antibody and Caninized PD-L1 Mouse Model as Translational Research Tools for the Study of Immunotherapy in Humans

12. Table S1 from Development of an Anti-canine PD-L1 Antibody and Caninized PD-L1 Mouse Model as Translational Research Tools for the Study of Immunotherapy in Humans

13. Saccharide analog, 2‐deoxy‐ <scp>d</scp> ‐glucose enhances 4‐1BB‐mediated antitumor immunity via PD‐L1 deglycosylation

14. Abstract 2969: Development of a canine PD-L1 antibody and caninized PD-L1 mouse model: an essential translational research tool to raise the success rate of immunotherapy in humans

16. Abstract P063: Tumor cell-derived lactic acid inhibit anti-tumor immunity in the immune checkpoint blockade resistant tumor

17. Phosphorylation of p53 at threonine 155 is required for Jab1-mediated nuclear export of p53

18. Cdk1 phosphorylation negatively regulates the activity of Net1 towards RhoA during mitosis

19. Controlling the switches: Rho GTPase regulation during animal cell mitosis

20. Rho GTPase independent regulation of ATM activation and cell survival by the RhoGEF Net1A

21. Rho GTPase–independent regulation of mitotic progression by the RhoGEF Net1

22. Regulation of Focal Adhesion Kinase Activation, Breast Cancer Cell Motility, and Amoeboid Invasion by the RhoA Guanine Nucleotide Exchange Factor Net1

23. Stress activated MAPKs and CRM1 regulate Net1A subcellular localization to control cell motility and invasion

24. MKRN1 Induces Degradation of West Nile Virus Capsid Protein by Functioning as an E3 Ligase

25. Minireview: Mouse Models of Rho GTPase Function in Mammary Gland Development, Tumorigenesis, and Metastasis

26. Jab1 Mediates Cytoplasmic Localization and Degradation of West Nile Virus Capsid Protein

27. Acetylation of the RhoA GEF Net1A controls its subcellular localization and activity

29. Regulation of ATM-Dependent DNA Damage Responses in Breast Cancer by the RhoGEF Net1

30. Hdm2 negatively regulates telomerase activity by functioning as an E3 ligase of hTERT

31. PML-IV functions as a negative regulator of telomerase by interacting with TERT

32. Differential regulation of p53 and p21 by MKRN1 E3 ligase controls cell cycle arrest and apoptosis

33. Jab1 as a mediator of nuclear export and cytoplasmic degradation of p53

34. Jab1 induces the cytoplasmic localization and degradation of p53 in coordination with Hdm2

36. Abstract 1782: Regulation of ATM-dependent DNA damage signaling in human breast cancer cells by the RhoGEF Net1A

37. West Nile virus capsid protein induces p53-mediated apoptosis via the sequestration of HDM2 to the nucleolus

38. Differential regulation of p53 and p21 by MKRN1 E3 ligase controls cell cycle arrest and apoptosis.

39. West Nile virus capsid protein induces p53-mediated apoptosis via the sequestration of HDM2 to the nucleolus.

40. MKRN1 Induces Degradation of West Nile Virus Capsid Protein by Functioning as an E3 Ligase.

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