Results 201 to 210 of about 1,174,650 (313)

Interaction with CYP20-3 limits OPDA flux into jasmonate biosynthesis in wounded leaves of arabidopsis grown at eCO₂. [PDF]

Front Plant Sci
Redl A, Gabriel J, van Dam NM, Bede JC.
europepmc   +1 more source

4‐Hydroxybenzyl Alcohol Mitigates Hyperlipidemia‐Associated Depression by Inhibiting Neuroinflammation via the NKIRAS2/NF‐κB Pathway

Advanced Science, EarlyView.
4‐HBA upregulates NKIRAS2 levels, inhibiting the activation of the NF‐κB pathway and subsequently reducing the levels of neuroinflammatory markers. This modulation helps restore normal mood and behavior in hyperlipidemic conditions, providing a potential therapeutic strategy for managing hyperlipidemia‐associated depression.
Ying Zhang, Meng Teng, Wenxuan He, Lanzhou Li, Yongfeng Zhang, Shimiao Wang, Chunyue Wang, Di Wang   +7 more
wiley   +1 more source

Coordination of Cyanobacterial Nitrate Assimilation and Photosynthesis by a Novel PsbO‐Interacting Protein PirN

Advanced Science, EarlyView.
PirN was identified as a previously uncharacterized PsbO‐interacting protein specifically induced in nitrate‐grown cyanobacteria. Loss of PirN leads to coordinated downregulation of PsbO and the nitrate reductase NarB, causing decreased PSII activity and impaired growth under nitrate conditions. Complementation with either PsbO or NarB largely restores
Chengcheng Huang, Zhen Xiao, Haitao Ge, Gaojie Wang, Jinghui Dong, Yan Wang, Hang Yang, Xing Wang, Hui Gao, Zhongshu Wang, Huanling Yang, Yuanya Zhang, Xiahe Huang, Wu Xu, Weimin Ma, Wenqiang Yang, Yingchun Wang   +16 more
wiley   +1 more source

The transcription factors GmSTF1 and GmSTF2 promote photosynthesis and lignin biosynthesis in soybean. [PDF]

aBIOTECH
Song Z, Zhao F, Bian Y, Li J, Wang W, Xu D.   +5 more
europepmc   +1 more source

A BioLiving Periosteum Evokes Centripetal Regeneration in Challenging Bone Defects

Advanced Science, EarlyView.
Large bone defects often suffer from insufficient central healing. This study engineers a BioLiving periosteum that mimics the native structure. It sequentially delivers remote chemical cues and contact physical cues in a signaling‐relay manner, effectively recruiting and guiding endogenous cells toward the defect center.
Yang Shi, Nian Liu, Jingyi Gu, Yinling Wang, Weiye Wang, Zhiwei Ke, Mingjun Xie, Wenjing Jin, Weicheng Kong, Jue Shi, Hui Pan, Yong He, Zhijian Xie   +12 more
wiley   +1 more source

Identification and characterization of 13 gene families encoding enzymes involved in flavonoid biosynthesis in barley and their roles under abiotic stress. [PDF]

Sci Rep
Mia MS, Jing X, Wani TA, Zargar S, Hasan MM, Yang T.   +5 more
europepmc   +1 more source

Gut Lactate Boosts Ruminococcus via Histone Lactylation to Mediate Time‐Restricted Feeding Protection in Crohn's Disease

Advanced Science, EarlyView.
TRF enriches Ruminococcus, a bacterial genus producing SCFAs, and activates the epithelial HIF‐1α signaling pathway. This mechanism protects the colonic mucosa from inflammatory insults in colitis models. Mechanistically, gut lactate production during starvation and refeeding mediates H4K12la, which increases SLC9A3 expression and creates an acidic gut
Linwen Huang, Huishi Tan, Senhui Weng, Yuntao Liu, Lingxu Song, Shaoyu Cheng, Zelong Lin, Jiawei Chen, Fei Tan, Jun Wang, Jinke Huang, Linkun Cai, Jiwei Chai, Cailing Zhong, Yanqiang Shi, Wendi Zhang, Haiyan Zhang, Chongyang Huang   +17 more
wiley   +1 more source

The AUTACE That Degrades KRAS and Engages CD8+ T Cells for the Treatment of KRAS/TP53 Co‐Mutant Tumors

Advanced Science, EarlyView.
AUTACE is a bifunctional nanoplatform that integrates tumor targeting, immune engagement, and on‐demand KRAS degradation. It targets KRAS/TP53 co‐mutant tumors via TP53‐specific TCRs, elicits antitumor CD8+ T‐cell responses through surface anti‐CD3 antibodies, and uses low‐intensity focused ultrasound (LIFU) to trigger controlled release of the KRAS ...
Luo Li, Bolin Li, Yanan Hao, Bo Pang, Pan Li, Chunli Li, Yu Tang   +6 more
wiley   +1 more source

Biosynthesis and assembly of mitochondrial proteins [PDF]

, 1983
A Scarpa, A Tzagoloff, AP Autor, AS Lewin, B Hennig, BC Pressman, C Côte, C Zwizinski, D Lloyd, DD Sabatini, DI Meyer, DI Meyer, DL Stigall, E Schmelzer, G Blobel, G Hallermayer, G Kreibich, G Macino, G Palade, G Schatz, G Schatz, GC Shore, H Freitag, H Freitag, H Korb, H Weiss, HW Heldt, J Subik, JG Conboy, JG Conboy, K Mihara, K Mihara, K Yamauchi, K Yamauchi, LAM Hensgens, M Klingenberg, M Mori, M Mori, M Schleyer, M Teintze, M-L Maccecchini, M-L Maccecchini, MA Harmey, N Nabi, N Nabi, N Nelson, N-H Chua, N-H Chua, P Böhni, P Sonderegger, P Sonderegger, P Walter, P Walter, P Walter, P Walter, PC Heinrich, PC Mcada, R Michel, R Sakakibara, R Zimmermann, R Zimmermann, R Zimmermann, R Zimmermann, RC Jackson, RN Dubois, S Matsuura, S Miura, SM Gasser, SN Graven, T Morita, W Neupert, W Sebald, W Wickner, Y Okada, Y Raymond, Y Raymond   +75 more
core   +1 more source