Results 211 to 220 of about 1,250,794 (338)

Exploring Functionally Enhanced BLP‐Trained Macrophage Subpopulations in S. Aureus Infection: Underlying Mechanisms and Therapeutic Significance

Advanced Science, EarlyView.
BLP‐trained macrophages show augmented resistance to infection, but their mechanisms remain unclear. scRNA‐seq identified 13 BMDM subsets, with two novel anti‐inflammatory/antibacterial subpopulations (C5/C7) emerging post‐BLP training. BLP training activates NRF2, attenuates oxidative stress/ferroptosis, and boosts glycolysis/OXPHOS. Adoptive transfer
Yantong Wan, Yinghao Hong, Xiangjun Ji, Jing Xiang, Jinxi Liu, Lixin Liang, Meng Ren, Wenhan Chen, Tengfei Xu, Zhijie Li, Tieliu Shi, Yong Jiang, Huaping Liang, Jinghua Liu   +13 more
wiley   +1 more source

Analysis of Genotypic Variations in the Anthocyanin Biosynthetic Pathway in Potatoes. [PDF]

Plant Direct
Lee CM, Shin SY, Park SJ, Park JS, Kim C, Kim HS, Lee HJ.   +6 more
europepmc   +1 more source

FATE OF DEUTERO-LABELED CARBAMYL GLUTAMATE IN CITRULLINE BIOSYNTHESIS

, 1954
Santiago Grisolı́a, R. H. Burris, P P Cohen   +2 more
openalex   +1 more source

SOME ASPECTS OF THE INDUCED BIOSYNTHESIS OF ALPHA-AMYLASE OF PSEUDOMONAS SACCHAROPHILA [PDF]

, 1955
Alvin Markovitz, Harold P. Klein
openalex   +1 more source

Skullcapflavone II Inhibits SLC1A4‐Mediated L‐Serine Uptake and Promotes Mitochondrial Damage in Gastric Cancer

Advanced Science, EarlyView.
Skullcapflavone II (SkII) significantly alters serine metabolism in gastric cancer cells by directly targeting the L‐serine transporter SLC1A4, thereby inhibiting L‐serine uptake rather than de novo synthesis. This disruption of serine metabolism by SkII leads to increased oxidative stress and consequent mitochondrial damage.
Jing Zhao, Yu‐Bo Ma, Rui‐Hong Xia, Zheng‐Chen Jiang, Ying Zhou, Ya‐Nan Wang, Meng‐Yan Yang, Jing‐Jie Dai, Tao Zhu, Li‐Bin Pan, Li Yuan   +10 more
wiley   +1 more source

Multi-omics integration reveals organ-specific biosynthesis of flavonoids and terpenoids in the medicinal plant <i>Bidens alba</i>. [PDF]

Front Plant Sci
Wang Z, Xu X, Zhang P, Huang Y, Zhao C, El-Kassaby YA, Chen Y, Wang J, Shi R.   +8 more
europepmc   +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

The GGH/HuR Complex Binds and Stabilizes mRNAs to Maintain Tumor Cell Cycle and DNA Replication

Advanced Science, EarlyView.
Despite its canonical role in inhibiting DNA synthesis, GGH promotes tumor growth as a novel RNA‐binding protein. GGH binds GC‐rich 5′UTRs (e.g., CDC6/CCND1), recruits HuR to form a ternary complex that stabilizes mRNA via circular conformation, fueling DNA replication and the cell cycle. Targeting this axis suppresses NSCLC progression.
Yu Li, Xinrui Li, Yuhui Du, Sijie Chen, Xiaoniu He, Zhangrong Xie, Zhiqing Zhou, Huijie Zhao, Xiaofei Zeng, Guoan Chen   +9 more
wiley   +1 more source

Gut microbiota related steroid hormone biosynthesis provide novel insights into high-salt diet related renal injury vit gut-kidney axis. [PDF]

BMC Microbiol
Liu TH, Xie T, Yu YS, Wang TT, Bai ZY, Zhu SY, Niu YH, Chen LG, Xiao Y, Wei H, Zhang CY.   +10 more
europepmc   +1 more source

5’‐Methylthioadenosine Metabolic Reprogramming Drives H3K79 Monomethylation‐Mediated PAK2 Upregulation to Promote Cadmium‐Induced Breast Cancer Progression by Impairing Autophagic Flux

Advanced Science, EarlyView.
Cadmium, a carcinogenic heavy metal, drives breast cancer progression via metabolic reprogramming and autophagic flux disruption. Multi‐omics revealed cadmium‐induced 5'‐methylthioadenosine depletion activates DOT1L‐mediated H3K79me1 at PAK2 promoter, upregulating PAK2 to block autophagy and driving malignancy. Clinically, 5'‐methylthioadenosine levels
Jingdian Li, Ping Deng, Tengfei Fan, Yuchen Qu, Miduo Tan, Yidan Liang, Peng Gao, Yongchun Peng, Mingke Qin, Sheng Jie, Rongrong Hao, Liting Wang, Lei Zhang, Chunhai Chen, Mindi He, Qinlong Ma, Yan Luo, Li Tian, Jia Xie, Mengyan Chen, Rui Tian, Min Li, Zhengping Yu, Zhou Zhou, Huifeng Pi   +24 more
wiley   +1 more source