Your search keyword '"Timour, Baslan"' showing total 2 results

1. DNA replication in early mammalian embryos is patterned, predisposing lamina-associated regions to fragility

Author

Shuangyi Xu, Ning Wang, Michael V. Zuccaro, Jeannine Gerhardt, Rajan Iyyappan, Giovanna Nascimento Scatolin, Zongliang Jiang, Timour Baslan, Amnon Koren, and Dieter Egli

Subjects

Science

Abstract

Abstract DNA replication in differentiated cells follows a defined program, but when and how it is established during mammalian development is not known. Here we show using single-cell sequencing, that late replicating regions are established in association with the B compartment and the nuclear lamina from the first cell cycle after fertilization on both maternal and paternal genomes. Late replicating regions contain a relative paucity of active origins and few but long genes and low G/C content. In both bovine and mouse embryos, replication timing patterns are established prior to embryonic genome activation. Chromosome breaks, which form spontaneously in bovine embryos at sites concordant with human embryos, preferentially locate to late replicating regions. In mice, late replicating regions show enhanced fragility due to a sparsity of dormant origins that can be activated under conditions of replication stress. This pattern predisposes regions with long neuronal genes to fragility and genetic change prior to separation of soma and germ cell lineages. Our studies show that the segregation of early and late replicating regions is among the first layers of genome organization established after fertilization.

Published

2024

2. Plasticity-induced repression of Irf6 underlies acquired resistance to cancer immunotherapy in pancreatic ductal adenocarcinoma

Author

Il-Kyu Kim, Mark S. Diamond, Salina Yuan, Samantha B. Kemp, Benjamin M. Kahn, Qinglan Li, Jeffrey H. Lin, Jinyang Li, Robert J. Norgard, Stacy K. Thomas, Maria Merolle, Takeshi Katsuda, John W. Tobias, Timour Baslan, Katerina Politi, Robert H. Vonderheide, and Ben Z. Stanger

Subjects

Science

Abstract

Abstract Acquired resistance to immunotherapy remains a critical yet incompletely understood biological mechanism. Here, using a mouse model of pancreatic ductal adenocarcinoma (PDAC) to study tumor relapse following immunotherapy-induced responses, we find that resistance is reproducibly associated with an epithelial-to-mesenchymal transition (EMT), with EMT-transcription factors ZEB1 and SNAIL functioning as master genetic and epigenetic regulators of this effect. Acquired resistance in this model is not due to immunosuppression in the tumor immune microenvironment, disruptions in the antigen presentation machinery, or altered expression of immune checkpoints. Rather, resistance is due to a tumor cell-intrinsic defect in T-cell killing. Molecularly, EMT leads to the epigenetic and transcriptional silencing of interferon regulatory factor 6 (Irf6), rendering tumor cells less sensitive to the pro-apoptotic effects of TNF-α. These findings indicate that acquired resistance to immunotherapy may be mediated by programs distinct from those governing primary resistance, including plasticity programs that render tumor cells impervious to T-cell killing.

Published

2024