Results 251 to 260 of about 3,812,700 (365)

Molecular Mimicry in Innate Immunity [PDF]

, 2009
Siew Leong Chan, Lieh Yoon Low, Simon Hsu, Sheng Li, Tong Liu, Eugenio Santelli, Gaëlle Le Negrate, John C. Reed, Virgil L. Woods, Jaime Pascual   +9 more
openalex   +1 more source

FOXQ1 Regulates Brain Endothelial Mitochondrial Function by Orchestrating Calcium Signaling and Cristae Morphology

Advanced Science, EarlyView.
FOXQ1 emerges as a master transcriptional regulator of brain endothelial metabolism, orchestrating mitochondrial function through dual control of calcium signaling and cristae organization. This study reveals that brain endothelial cells rely on oxidative phosphorylation rather than glycolysis alone, challenging the current metabolic paradigm and ...
Wenzheng Zou, Yuqing Lv, Lin Li, Shukui Zhang, Jiaqi Liang, Chengchao Wu, Enyu Huang, Jianwei Jiao, Jingjing Zhang   +8 more
wiley   +1 more source

Leptospiral presentation in Behçet's disease: A case report

Journal of the Formosan Medical Association, 2020
Tai-Li Chen, Lih-shinn Wang
doaj   +1 more source

Molecular mimicry of HIV gp120: Possible implications on prevention and therapy of AIDS

, 2005
Nevena Veljković
openalex   +2 more sources

Primary biliary cirrhosis, bacteria and molecular mimicry: what's the molecule and where's the mimic? [PDF]

, 2009
Shawn Wasilenko, Gina E. Mason, Andrew L. Mason   +2 more
openalex   +1 more source

A Study on the Cell Layer Patterns of a Citrus Periclinal Chimera Reveals β‐Cryptoxanthin Regulation in Citrus Fruits

Advanced Science, EarlyView.
Researchers have identified a citrus chimera with distinctive tissue origins and carotenoid profiles. It is discovered that fruit tissues develop from all three cell layers but in different proportions. A key transcription factor, MYB107, regulates β‐cryptoxanthin production by directly activating carotenoid biosynthesis genes, explaining why some ...
Chi Zhang, Kaijie Zhu, Zhehui Zhang, Huiyu Ji, Qun Wu, Lin Zhang, Fuzhi Ke, Gang Wang, Min Zhang   +8 more
wiley   +1 more source

Bioinformatics analysis of myelin-microbe interactions suggests multiple types of molecular mimicry in the pathogenesis of multiple sclerosis. [PDF]

PLoS One
Bigdeli A, Ghaderi-Zefrehei M, Lesch BJ, Behmanesh M, Arab SS.   +4 more
europepmc   +1 more source

Molecular mimicry in the chronic myeloproliferative disorders: reciprocity between quantitative JAK2 V617F and Mpl expression

, 2006
Alison R. Moliterno, Donna M. Williams, Ophelia Rogers, Jerry L. Spivak   +3 more
openalex   +1 more source

Molecular mimicry between streptococcal pyrogenic exotoxin B and endothelial cells [PDF]

, 2010
Yueh-Hsia Luo, Woei‐Jer Chuang, Jiunn-Jong Wu, Ming‐Tai Lin, Ching‐Chuan Liu, Pao-Yen Lin, Jun‐Neng Roan, Tak‐Wah Wong, Yuh-Ling Chen, Yee-Shin Lin   +9 more
openalex   +1 more source

PCSK9 Loss‐of‐Function Disrupts Cellular Microfilament Network via LIN28A/HES5/JMY Axis in Neural Tube Defects

Advanced Science, EarlyView.
PCSK9 acts as a molecular chaperone promoting LIN28A lysosomal degradation. LIN28A elevates transcription factor HES5, increasing JMY expression. PCSK9 loss causes neural tube defects (NTDs) by disrupting the LIN28A/HES5/JMY axis, and high JMY disorganizes the neural progenitor cell microfilament network, leading to incomplete neural tube structure in ...
Xiaoshuai Li, Rui Wang, Wenting Luo, Hui Gu, Tianchu Huang, Qiushi Wang, Zhengwei Yuan   +6 more
wiley   +1 more source