@lianagoehring.bsky.social
Reposted
What happens when you overexpress one subunit of the RNA Pol II? Well, it depends on the subunit, but all deregulate transcription and induce genome instability @agagambus.bsky.social www.biorxiv.org/content/10.1...
RNA Polymerase II subunits overexpressions induce genome instability and deregulate transcription
Independently of the pathways or circuits deregulated in cancer cells, these present altered transcription patterns, often also direct consequence of deregulation of transcription factors. In this sen...
www.biorxiv.org
November 21, 2024 at 10:06 AM
What happens when you overexpress one subunit of the RNA Pol II? Well, it depends on the subunit, but all deregulate transcription and induce genome instability @agagambus.bsky.social www.biorxiv.org/content/10.1...
Very excited to share this work led by @denizgoekbuget.bsky.social!
🚨 New Paper Alert! 🚨
Our latest study on KMT2C/KMT2D (mutated in 20% of cancers) reveals a new function for H3K4me1 in regulating DNA replication timing (RT) and origin activity during cell state transitions. Check it out: www.cell.com/cell-reports.... More info ⬇️
Our latest study on KMT2C/KMT2D (mutated in 20% of cancers) reveals a new function for H3K4me1 in regulating DNA replication timing (RT) and origin activity during cell state transitions. Check it out: www.cell.com/cell-reports.... More info ⬇️
KMT2C/KMT2D-dependent H3K4me1 mediates changes in DNA replication timing and origin activity during a cell fate transition
Gökbuget et al. use machine learning to quantify chromatin state changes that predict
DNA replication timing changes during cell differentiation. By following up on top
predictors through functional v...
www.cell.com
February 4, 2025 at 5:14 PM
Very excited to share this work led by @denizgoekbuget.bsky.social!
Reposted
🚨 New Paper Alert! 🚨
Our latest study on KMT2C/KMT2D (mutated in 20% of cancers) reveals a new function for H3K4me1 in regulating DNA replication timing (RT) and origin activity during cell state transitions. Check it out: www.cell.com/cell-reports.... More info ⬇️
Our latest study on KMT2C/KMT2D (mutated in 20% of cancers) reveals a new function for H3K4me1 in regulating DNA replication timing (RT) and origin activity during cell state transitions. Check it out: www.cell.com/cell-reports.... More info ⬇️
KMT2C/KMT2D-dependent H3K4me1 mediates changes in DNA replication timing and origin activity during a cell fate transition
Gökbuget et al. use machine learning to quantify chromatin state changes that predict
DNA replication timing changes during cell differentiation. By following up on top
predictors through functional v...
www.cell.com
February 4, 2025 at 5:06 PM
🚨 New Paper Alert! 🚨
Our latest study on KMT2C/KMT2D (mutated in 20% of cancers) reveals a new function for H3K4me1 in regulating DNA replication timing (RT) and origin activity during cell state transitions. Check it out: www.cell.com/cell-reports.... More info ⬇️
Our latest study on KMT2C/KMT2D (mutated in 20% of cancers) reveals a new function for H3K4me1 in regulating DNA replication timing (RT) and origin activity during cell state transitions. Check it out: www.cell.com/cell-reports.... More info ⬇️
Reposted
🧪1/ 🚨New paper on ecDNAs from our lab!
We reveal a strategy to engineer extrachromosomal DNA (ecDNA) amplifications in cells & mice. Let's dive in! Let’s dive in! 🧵👇
www.nature.com/articles/s41...
We reveal a strategy to engineer extrachromosomal DNA (ecDNA) amplifications in cells & mice. Let's dive in! Let’s dive in! 🧵👇
www.nature.com/articles/s41...
Engineered extrachromosomal oncogene amplifications promote tumorigenesis - Nature
Large extrachromosomal DNAs are engineered using a CRISPR- and Cre–loxP-based approach and shown to drive cancer in mouse models, with potential applications in determining the role of oncogene a...
www.nature.com
December 18, 2024 at 4:54 PM
🧪1/ 🚨New paper on ecDNAs from our lab!
We reveal a strategy to engineer extrachromosomal DNA (ecDNA) amplifications in cells & mice. Let's dive in! Let’s dive in! 🧵👇
www.nature.com/articles/s41...
We reveal a strategy to engineer extrachromosomal DNA (ecDNA) amplifications in cells & mice. Let's dive in! Let’s dive in! 🧵👇
www.nature.com/articles/s41...