Your search keyword '"Wang, Li‐Chin"' showing total 3 results

1. Linear interaction between replication and transcription shapes DNA break dynamics at recurrent DNA break Clusters.

Author

Corazzi, Lorenzo, Ionasz, Vivien S., Andrejev, Sergej, Wang, Li-Chin, Vouzas, Athanasios, Giaisi, Marco, Di Muzio, Giulia, Ding, Boyu, Marx, Anna J. M., Henkenjohann, Jonas, Allers, Michael M., Gilbert, David M., and Wei, Pei-Chi

Abstract

Recurrent DNA break clusters (RDCs) are replication-transcription collision hotspots; many are unique to neural progenitor cells. Through high-resolution replication sequencing and a capture-ligation assay in mouse neural progenitor cells experiencing replication stress, we unravel the replication features dictating RDC location and orientation. Most RDCs occur at the replication forks traversing timing transition regions (TTRs), where sparse replication origins connect unidirectional forks. Leftward-moving forks generate telomere-connected DNA double-strand breaks (DSBs), while rightward-moving forks lead to centromere-connected DSBs. Strand-specific mapping for DNA-bound RNA reveals co-transcriptional dual-strand DNA:RNA hybrids present at a higher density in RDC than in other actively transcribed long genes. In addition, mapping RNA polymerase activity uncovers that head-to-head interactions between replication and transcription machinery result in 60% DSB contribution to the head-on compared to 40% for co-directional. Taken together we reveal TTR as a fragile class and show how the linear interaction between transcription and replication impacts genome stability.In neural progenitor cells, recurrent DNA break clusters (RDCs) occur to genes crucial for brain function. Here the authors find that most RDCs emerge at long-traveling unidirectional replication forks, and often unrelated to R-loops. [ABSTRACT FROM AUTHOR]

Published

2024

2. Altered assembly paths mitigate interference among paralogous complexes.

Author

Yeh CW, Hsu KL, Lin ST, Huang WC, Yeh KH, Liu CJ, Wang LC, Li TT, Chen SC, Yu CH, Leu JY, Yeang CH, and Yen HS

Subjects

Protein Stability, Evolution, Molecular, Protein Subunits metabolism, Protein Subunits chemistry, Protein Multimerization, Protein Binding, Gene Duplication, Multiprotein Complexes metabolism, Multiprotein Complexes chemistry, Multiprotein Complexes genetics

Abstract

Protein complexes are fundamental to all cellular processes, so understanding their evolutionary history and assembly processes is important. Gene duplication followed by divergence is considered a primary mechanism for diversifying protein complexes. Nonetheless, to what extent assembly of present-day paralogous complexes has been constrained by their long evolutionary pathways and how cross-complex interference is avoided remain unanswered questions. Subunits of protein complexes are often stabilized upon complex formation, whereas unincorporated subunits are degraded. How such cooperative stability influences protein complex assembly also remains unclear. Here, we demonstrate that subcomplexes determined by cooperative stabilization interactions serve as building blocks for protein complex assembly. We further develop a protein stability-guided method to compare the assembly processes of paralogous complexes in cellulo. Our findings support that oligomeric state and the structural organization of paralogous complexes can be maintained even if their assembly processes are rearranged. Our results indicate that divergent assembly processes by paralogous complexes not only enable the complexes to evolve new functions, but also reinforce their segregation by establishing incompatibility against deleterious hybrid assemblies., (© 2024. The Author(s).)

Published

2024

3. Linear Interaction Between Replication and Transcription Shapes DNA Break Dynamics at Recurrent DNA Break Clusters.

Author

Corazzi L, Ionasz V, Andrejev S, Wang LC, Vouzas A, Giaisi M, Di Muzio G, Ding B, Marx AJM, Henkenjohann J, Allers MM, Gilbert DM, and Wei PC

Abstract

Recurrent DNA break clusters (RDCs) are replication-transcription collision hotspots; many are unique to neural progenitor cells. Through high-resolution replication sequencing and a capture-ligation assay in mouse neural progenitor cells experiencing replication stress, we unraveled the replication features dictating RDC location and orientation. Most RDCs occur at the replication forks traversing timing transition regions (TTRs), where sparse replication origins connect unidirectional forks. Leftward-moving forks generate telomere-connected DNA double-strand breaks (DSBs), while rightward-moving forks lead to centromere-connected DSBs. Strand-specific mapping for DNA-bound RNA revealed co-transcriptional dual-strand DNA:RNA hybrids present at a higher density in RDC than in other actively transcribed long genes. In addition, mapping RNA polymerase activity revealed that head-to-head interactions between replication and transcription machinery resulted in 60% DSB contribution to the head-on compared to 40% for co-directional. Our findings revealed TTR as a novel fragile class and highlighted how the linear interaction between transcription and replication impacts genome stability.

Published

2024