4433-40-3Relevant articles and documents
-
Johnson,Litzinger
, p. 1940 (1936)
-
Bioorthogonal Chemical Signature Enabling Amplified Visualization of Cellular Oxidative Thymines
Bai, Min,Cao, Xiaowen,Chen, Feng,Xue, Jing,Zhao, Yue,Zhao, Yongxi
, p. 10495 - 10501 (2021)
Cellular oxidative thymines, 5-hydroxymethyluracil (5hmU) and 5-formyluracil (5fU), are found in the genomes of a diverse range of organisms, the distribution of which profoundly influence biological processes and living systems. However, the distribution of cellular oxidative thymines has not been explored because of lacking both specific bioorthogonal labeling and sensitivity methods for single-cell analysis. Herein, we report a bioorthogonal chemical signature enabling amplified visualization of cellular oxidative thymines in single cells. The synthesized ATP-γ-alkyne, an ATP analogue with bioorthogonal tag modified on γ-phosphate can be specifically linked to cellular 5hmU by chemoenzymatic labeling. DNA with 5-alkynephosphomethyluracil were then clicked with azide (N3)-modified 5hmU-primer. Identification of 5fU is based on selective reduction from 5fU to 5hmU, subsequent chemoenzymatic labeling of the newly generated 5hmU, and cross-linking with N3-modified 5fU-primer via click chemistry. Then, all of the 5hmU and 5fU sites are encoded with respective circularized barcodes. These barcodes are simultaneously amplified for multiplexed single-molecule imaging. The above two kinds of barcodes can be simultaneously amplified for differentiated visualization of 5hmU and 5fU in single cells. We find these two kinds of cellular oxidative thymines are spatially organized in a cell-type-dependent style with cell-to-cell heterogeneity. We also investigate their multilevel subcellular information and explore their dynamic changes during cell cycles. Further, using DNA sequencing instead of fluorescence imaging, our proposed bioorthogonal chemical signature holds great potential to offer the sequence information of these oxidative thymines in cells and may provide a reliable chemical biology approach for studying the whole-genome oxidative thymines profiles and insights into their functional role and dynamics in biology.
BICYCLIC KINASE INHIBITORS AND USES THEREOF
-
Paragraph 613; 618, (2021/11/06)
The invention relates to kinase inhibitors, in particular inhibitors of protein kinases including the SIK-family, CSF1R, HCK, TEK-family, BRK, ABL, KIT and/or their mutants. Although structurally similar to other bicyclic kinase inhibitors, the kinase inhibitors of the invention are distinctive; possessing a particular class of heterocyclic moiety. Such kinase inhibitors can display one or more certain properties distinct to their structurally similar kinase inhibitors. The kinase inhibitors of the invention or pharmaceutical compositions comprising them may be used in the treatment of a disorder or condition, such as a proliferative disorder, for example, a leukaemia or solid tumour. In particular, these and other structurally related kinase inhibitors may be used in the treatment of a proliferative disorder - such as a mixed phenotype acute leukaemia (MPAL) - characterised by (inter-alia) the presence of MEF2C protein, a human chromosomal translocation at 11q23, and/or a KMT2A fusion oncoprotein. The kinase inhibitors or pharmaceutical compositions of the invention may be used topically to modulate skin pigmentation in a subject, for example to impart UV protection and reduce skin cancer risk.
FGFR4 Inhibitor. Compositions and their use in pharmaceutical preparations
-
Paragraph 0057-0060, (2021/10/27)
The invention provides 3 inhibitor which takes 4 - 4 dihydropyrimidine [5 - d,2] pyrimidine - (1H) FGFR4 ketone as a mother nucleus and has a covalent structure. The examples give 9 specific compounds and kinase inhibitory activity testing of these 9 compounds, wherein LX08 for FGFR4 kinase inhibitory activity is only 7 nm, lower than FIIN - 2 of the active control, and potential application prospects. In addition, by subjecting the synthesized compound to MALDI-TOF mass spectrometry, we found that compounds of LX01, LX05, LX06, LX07, LX08 are covalently bound to FGFR4 of Cys552, cannot covalently bind FGFR4 of Cys477, and LX09 are FGFR4 inhibitors which can be covalently bound to the two cysteines Cys552 and Cys477 in FGFR4.