Your search keyword '"CHANG, C. W."' showing total 4 results

1. Intrinsic fluence non-uniformity in D3He backlit proton radiography.

Author

Johnson, T. M., Shan, J., Kishimori, R., Cufari, M. J., Adrian, P. J., Buschmann, B., Chang, C. W., Dannhoff, S. G., DeVault, A., Evans, T. E., Foo, B., Kunimune, J. H., Lawrence, Y., Pearcy, J. A., Reichelt, B. L., Russell, L., Sutcliffe, G. D., Vanderloo, N. L., Vargas, J., and Wink, C.

Subjects

NUCLEAR track detectors, PARTICLE physics, PHYSICS experiments, PROTONS, MAGNETIC fields

Abstract

Proton radiography is an essential diagnostic for studying magnetic fields in high energy density physics experiments. Protons are born in a fusion implosion, traverse the plasma, and are detected on CR-39 solid state nuclear track detectors. Here, it is shown that there is an intrinsic non-uniformity in ∼ 15 MeV D3He proton radiography data. The increasing angle between the proton trajectory and the center of the detector results in the proton traveling through more detector stack material. As the protons travel through more material and lose energy, the proton energy spectrum gets wider. Protons at the lower end of the spectrum can therefore be lost. The nominal filtering results in protons being ranged out at large angles, causing the intrinsic non-uniformity. This angular effect is confirmed with both OMEGA experiments and Geant4 simulations. It is found that reducing the filtering between the pieces of CR-39 in the detector stack mitigates this effect. Results from accelerator experiments show that this reduced filtering does not impact the detection efficiency of the CR-39. Accounting for this intrinsic fluence non-uniformity is essential for magnetic field reconstruction techniques using proton radiographs. [ABSTRACT FROM AUTHOR]

Published

2024

2. Quantum simulation of the bosonic Kitaev chain

Author

Busnaina, Jamal H., primary, Shi, Zheng, additional, McDonald, Alexander, additional, Dubyna, Dmytro, additional, Nsanzineza, Ibrahim, additional, Hung, Jimmy S. C., additional, Chang, C. W. Sandbo, additional, Clerk, Aashish A., additional, and Wilson, Christopher M., additional

Published

2024

3. Insights into optimal surgical fixation for posterior malleolar fractures: a network meta-analysis.

Author

Su, Y-C., Wang, Y-Y., Fang, C-J., Tu, Y-K., Chang, C-W., Kuan, F-C., Hsu, K-L., and Shih, C-A.

Published

2024

4. BGLF4 kinase regulates the formation of the EBV cytoplasmic assembly compartment and the recruitment of cellular IQGAP1 for virion release.

Author

Dai Y-C, Yeh S-Y, Cheng Y-Y, Huang W-H, Liou G-G, Yang T-Y, Chang C-Y, Fang T-F, Chang C-W, Su M-T, Lee C-P, and Chen M-R

Subjects

Humans, Capsid Proteins metabolism, Epstein-Barr Virus Infections metabolism, Epstein-Barr Virus Infections virology, Membrane Proteins metabolism, Endoplasmic Reticulum metabolism, Endosomes metabolism, Golgi Apparatus metabolism, Cytoplasm metabolism, Cytoplasm virology, Herpesvirus 4, Human chemistry, Herpesvirus 4, Human genetics, Herpesvirus 4, Human growth & development, Herpesvirus 4, Human metabolism, Protein Serine-Threonine Kinases metabolism, ras GTPase-Activating Proteins metabolism, Viral Proteins metabolism, Virion chemistry, Virion growth & development, Virion metabolism, Virus Assembly physiology, Virus Release

Abstract

After Epstein-Barr virus (EBV) genome replication and encapsidation in the nucleus, nucleocapsids are translocated into the cytoplasm for subsequent tegumentation and maturation. The EBV BGLF4 kinase, which induces partial disassembly of the nuclear lamina, and the nuclear egress complex BFRF1/BFLF2 coordinately facilitate the nuclear egress of nucleocapsids. Here, we demonstrate that within EBV reactivated epithelial cells, viral capsids, tegument proteins, and glycoproteins are clustered in the juxtanuclear concave region, accompanied by redistributed cytoplasmic organelles and the cytoskeleton regulator IQ-domain GTPase-activation protein 1 (IQGAP1), close to the microtubule-organizing center (MTOC). The assembly compartment (AC) structure was diminished in BGLF4-knockdown TW01-EBV cells and BGLF4-knockout bacmid-carrying TW01 cells, suggesting that the formation of AC structure is BGLF4-dependent. Notably, glycoprotein gp350/220 was observed by confocal imaging to be distributed in the perinuclear concave region and surrounded by the endoplasmic reticulum (ER) membrane marker calnexin, indicating that the AC may be located within a globular structure derived from ER membranes, adjacent to the outer nuclear membrane. Moreover, the viral capsid protein BcLF1 and tegument protein BBLF1 were co-localized with IQGAP1 near the cytoplasmic membrane in the late stage of replication. Knockdown of IQGAP1 did not affect the AC formation but decreased virion release from both TW01-EBV and Akata + cells, suggesting IQGAP1-mediated trafficking regulates EBV virion release. The data presented here show that BGLF4 is required for cytoskeletal rearrangement, coordination with the redistribution of cytoplasmic organelles and IQGAP1 for virus maturation, and subsequent IQGAP1-dependent virion release.IMPORTANCEEBV genome is replicated and encapsidated in the nucleus, and the resultant nucleocapsids are translocated to the cytoplasm for subsequent virion maturation. We show that a cytoplasmic AC, containing viral proteins, markers of the endoplasmic reticulum, Golgi, and endosomes, is formed in the juxtanuclear region of epithelial and B cells during EBV reactivation. The viral BGLF4 kinase contributes to the formation of the AC. The cellular protein IQGAP1 is also recruited to the AC and partially co-localizes with the virus capsid protein BcLF1 and tegument protein BBLF1 in EBV-reactivated cells, dependent on the BGLF4-induced cytoskeletal rearrangement. In addition, virion release was attenuated in IQGAP1-knockdown epithelial and B cells after reactivation, suggesting that IQGAP1-mediated trafficking may regulate the efficiency of virus maturation and release., Competing Interests: The authors declare no conflict of interest.

Published

2024