Your search keyword '"Lopez-Pajares V"' showing total 3 results

1. 417 p63 cooperates with FOXK1 to mediate oncogenic 3D chromatin dynamics

Author

Lopez-Pajares, V., Jung, N., Donohue, L., Guo, M., and Khavari, P.A.

Published

2024

2. Glucose binds and activates NSUN2 to promote translation and epidermal differentiation.

Author

Miao W, Porter DF, Li Y, Meservey LM, Yang YY, Ma C, Ferguson ID, Tien VB, Jack TM, Ducoli L, Lopez-Pajares V, Tao S, Savage PB, Wang Y, and Khavari PA

Abstract

Elevations in intracellular glucose concentrations are essential for epithelial cell differentiation by mechanisms that are not fully understood. Glucose has recently been found to directly bind several proteins to alter their functions to enhance differentiation. Among the newly identified glucose-binding proteins is NSUN2, an RNA-binding protein that we identified as indispensable for epidermal differentiation. Glucose was found to bind conserved sequences within NSUN2, enhancing its binding to S-adenosyl-L-methionine and boosting its enzymatic activity. Additionally, glucose enhanced NSUN2's proximity to proteins involved in mRNA translation, with NSUN2 modulating global messenger RNA (mRNA) translation, particularly that of key pro-differentiation mRNAs containing m5C modifications, such as GRHL3. Glucose thus engages diverse molecular mechanisms beyond its energetic roles to facilitate cellular differentiation processes., (© The Author(s) 2024. Published by Oxford University Press on behalf of Nucleic Acids Research.)

Published

2024

3. Disease-Linked Regulatory DNA Variants and Homeostatic Transcription Factors in Epidermis.

Author

Porter DF, Meyers RM, Miao W, Reynolds DL, Hong AW, Yang X, Mondal S, Siprashvili Z, Srinivasan S, Ducoli L, Meyers JM, Nguyen DT, Ko LA, Kellman L, Elfaki I, Guo M, Winge MC, Lopez-Pajares V, Porter IE, Tao S, and Khavari PA

Abstract

Identifying noncoding single nucleotide variants ( SNVs ) in regulatory DNA linked to polygenic disease risk, the transcription factors ( TFs ) they bind, and the target genes they dysregulate is a goal in polygenic disease research. Massively parallel reporter gene analysis ( MPRA ) of 3,451 SNVs linked to risk for polygenic skin diseases characterized by disrupted epidermal homeostasis identified 355 differentially active SNVs ( daSNVs ). daSNV target gene analysis, combined with daSNV editing, underscored dysregulated epidermal differentiation as a pathomechanism shared across common polygenic skin diseases. CRISPR knockout screens of 1772 human TFs revealed 108 TFs essential for epidermal progenitor differentiation, uncovering novel roles for ZNF217, CXXC1, FOXJ2, IRX2 and NRF1. Population sampling CUT&RUN of 27 homeostatic TFs identified allele-specific DNA binding ( ASB ) differences at daSNVs enriched near epidermal homeostasis and monogenic skin disease genes, with notable representation of SP/KLF and AP-1/2 TFs. This resource implicates dysregulated differentiation in risk for diverse polygenic skin diseases.

Published

2024