Project description:The RNA binding protein paralogs LIN28A and LIN28B play critical roles in embryonic development, tumorigenesis, and pluripotency. Somatic cells can be reprogrammed to induced pluripotent stem (iPS) cells by overexpression of OCT4 and SOX2 together with NANOG and LIN28A (OSNA), but the exact roles LIN28A/B play are still poorly understood. Here we show that LIN28B likewise promotes reprogramming, and that reactivation of both endogenous LIN28A and B loci are required for maximal reprogramming efficiency. The LIN28B locus has open chromatin and is activated early during reprogramming, whereas LIN28A is activated at later stages by OCT4, marking the transition to bona fide iPS cells. By proteomic and metabolomic analysis, we demonstrate that LIN28A chiefly regulates let-7 and protein translation, whereas LIN28B promotes embryonic metabolism by repressing oxidative phosphorylation and enhancing glycolysis. Thus, LIN28A and LIN28B play independent and cooperative roles in reprogramming and pluripotent stem cell metabolism. 8 samples in total were analyzed. 2 replicates for each phenotypes. Controls are the wild type (flox) without lin28a/b loss of function.

Project description:The RNA binding protein paralogs LIN28A and LIN28B play critical roles in embryonic development, tumorigenesis, and pluripotency. Somatic cells can be reprogrammed to induced pluripotent stem (iPS) cells by overexpression of OCT4 and SOX2 together with NANOG and LIN28A (OSNA), but the exact roles LIN28A/B play are still poorly understood. Here we show that LIN28B likewise promotes reprogramming, and that reactivation of both endogenous LIN28A and B loci are required for maximal reprogramming efficiency. The LIN28B locus has open chromatin and is activated early during reprogramming, whereas LIN28A is activated at later stages by OCT4, marking the transition to bona fide iPS cells. By proteomic and metabolomic analysis, we demonstrate that LIN28A chiefly regulates let-7 and protein translation, whereas LIN28B promotes embryonic metabolism by repressing oxidative phosphorylation and enhancing glycolysis. Thus, LIN28A and LIN28B play independent and cooperative roles in reprogramming and pluripotent stem cell metabolism.

Project description:Lin28A and its paralog Lin28B are RNA binding proteins that regulate gene expression by inhibition of the maturation of the Per/Pri Let-7 miRNAs family and also via Let-7 independent mechanism. To study the effect of Lin28A ectopic-expression on mouse embryonic development we used a transgenic mice strain that combine a Cre-Lox system and a Tet-On system (herein Lox-stop-Lox-TetOn-Lin28A mice) and enable spatial and temporal control of transgenic Lin28A over-expression. Here we show that global Lin28A over-expression (by crossing Lox-stop-Lox-TetOn-Lin28A males with VasaCre females) in the mouse embryo prevents embryonic lung development. To study the precise developmental stage affected by Lin28A expression we preformed RNA sequencing analysis for transgenic and control lungs from E12.5, E14.5, E16.5 and E18.5 embryos. This analysis revealed that the development of the lung was delayed but not completely abrogated by Lin28A expression. We further showed that the effect of Lin28A expression in the mesenchymal cells (by crossing Lox-stop-Lox-TetOn-Lin28A males with Wt1Cre females) of the lung leads to the same phenotype as global Lin28A expression while expression in the lung epithelial cells (by crossing the Lox-stop-Lox-TetOn-Lin28A males with Nkx2.1Cre females) result in a milder developmental phenotype.

Project description:The naïve pluripotent epiblast cells become polarized into a rosette-like structure, followed by irreversible transition into primed pluripotency during one of the fastest morphological switches termed lumenogenesis. This requires rapid decay of pluripotency-associated mRNAs, but the underlying mechanism remains unknown. Guided by machine learning and metabolic RNA sequencing, we identified RNA binding proteins (RBPs), especially LIN28A, as primary mRNA decay factors. To understand if RBP dynamics steer embryogenesis, we used mRNA-RBP interactome capture during naïve-rosette-epiblast-gastrulation progression. We identified a dramatic increase in LIN28A mRNA binding, driven by its nucleolus-to-cytoplasm translocation during the naïve-primed pluripotency transition. Cytoplasmic LIN28A binds to 3’UTRs of pluripotency-associated mRNAs to directly stimulate their decay, and thereby progression to lumenogenesis. Accordingly, forced nuclear retention of LIN28A impeded lumenogenesis, causing an unforeseen embryonic multiplication and impaired gastrulation. This reveals selective mRNA decay, driven by nucleo-cytoplasmic RBP translocation, as an intrinsic mechanism for cell identity switch that controls embryonic timing of lumenogenesis.

Project description:The naïve pluripotent epiblast cells become polarized into a rosette-like structure, followed by irreversible transition into primed pluripotency during one of the fastest morphological switches termed lumenogenesis. This requires rapid decay of pluripotency-associated mRNAs, but the underlying mechanism remains unknown. Guided by machine learning and metabolic RNA sequencing, we identified RNA binding proteins (RBPs), especially LIN28A, as primary mRNA decay factors. To understand if RBP dynamics steer embryogenesis, we used mRNA-RBP interactome capture during naïve-rosette-epiblast-gastrulation progression. We identified a dramatic increase in LIN28A mRNA binding, driven by its nucleolus-to-cytoplasm translocation during the naïve-primed pluripotency transition. Cytoplasmic LIN28A binds to 3’UTRs of pluripotency-associated mRNAs to directly stimulate their decay, and thereby progression to lumenogenesis. Accordingly, forced nuclear retention of LIN28A impeded lumenogenesis, causing an unforeseen embryonic multiplication and impaired gastrulation. This reveals selective mRNA decay, driven by nucleo-cytoplasmic RBP translocation, as an intrinsic mechanism for cell identity switch that controls embryonic timing of lumenogenesis.

Project description:The naïve pluripotent epiblast cells become polarized into a rosette-like structure, followed by irreversible transition into primed pluripotency during one of the fastest morphological switches termed lumenogenesis. This requires rapid decay of pluripotency-associated mRNAs, but the underlying mechanism remains unknown. Guided by machine learning and metabolic RNA sequencing, we identified RNA binding proteins (RBPs), especially LIN28A, as primary mRNA decay factors. To understand if RBP dynamics steer embryogenesis, we used mRNA-RBP interactome capture during naïve-rosette-epiblast-gastrulation progression. We identified a dramatic increase in LIN28A mRNA binding, driven by its nucleolus-to-cytoplasm translocation during the naïve-primed pluripotency transition. Cytoplasmic LIN28A binds to 3’UTRs of pluripotency-associated mRNAs to directly stimulate their decay, and thereby progression to lumenogenesis. Accordingly, forced nuclear retention of LIN28A impeded lumenogenesis, causing an unforeseen embryonic multiplication and impaired gastrulation. This reveals selective mRNA decay, driven by nucleo-cytoplasmic RBP translocation, as an intrinsic mechanism for cell identity switch that controls embryonic timing of lumenogenesis.

Project description:The naïve pluripotent epiblast cells become polarized into a rosette-like structure, followed by irreversible transition into primed pluripotency during one of the fastest morphological switches termed lumenogenesis. This requires rapid decay of pluripotency-associated mRNAs, but the underlying mechanism remains unknown. Guided by machine learning and metabolic RNA sequencing, we identified RNA binding proteins (RBPs), especially LIN28A, as primary mRNA decay factors. To understand if RBP dynamics steer embryogenesis, we used mRNA-RBP interactome capture during naïve-rosette-epiblast-gastrulation progression. We identified a dramatic increase in LIN28A mRNA binding, driven by its nucleolus-to-cytoplasm translocation during the naïve-primed pluripotency transition. Cytoplasmic LIN28A binds to 3’UTRs of pluripotency-associated mRNAs to directly stimulate their decay, and thereby progression to lumenogenesis. Accordingly, forced nuclear retention of LIN28A impeded lumenogenesis, causing an unforeseen embryonic multiplication and impaired gastrulation. This reveals selective mRNA decay, driven by nucleo-cytoplasmic RBP translocation, as an intrinsic mechanism for cell identity switch that controls embryonic timing of lumenogenesis.

Project description:The naïve pluripotent epiblast cells become polarized into a rosette-like structure, followed by irreversible transition into primed pluripotency during one of the fastest morphological switches termed lumenogenesis. This requires rapid decay of pluripotency-associated mRNAs, but the underlying mechanism remains unknown. Guided by machine learning and metabolic RNA sequencing, we identified RNA binding proteins (RBPs), especially LIN28A, as primary mRNA decay factors. To understand if RBP dynamics steer embryogenesis, we used mRNA-RBP interactome capture during naïve-rosette-epiblast-gastrulation progression. We identified a dramatic increase in LIN28A mRNA binding, driven by its nucleolus-to-cytoplasm translocation during the naïve-primed pluripotency transition. Cytoplasmic LIN28A binds to 3’UTRs of pluripotency-associated mRNAs to directly stimulate their decay, and thereby progression to lumenogenesis. Accordingly, forced nuclear retention of LIN28A impeded lumenogenesis, causing an unforeseen embryonic multiplication and impaired gastrulation. This reveals selective mRNA decay, driven by nucleo-cytoplasmic RBP translocation, as an intrinsic mechanism for cell identity switch that controls embryonic timing of lumenogenesis.

Project description:Lin28a or Lin28b single knockout or double knockout MEF cells reprogrammed to iPS cells Lin28a or Lin28b single knockout or double knockout MEF cells reprogrammed to iPS cells

Project description:LIN28 (also known as LIN28A), a highly conserved RNA-binding protein, has emerged as a central post-transcriptional regulator of cell fate through blockade of let-7 microRNA (miRNA) biogenesis and direct modulation of mRNA translation. To gain insight into how LIN28 is integrated with the pluripotency signaling network, we investigated the role of LIN28 phosphorylation. We employed a targeted phosphoproteomics strategy in mouse ESCs (mESCs) and were able to map four phosphosites, two of which, S184 and S200, were confidently assigned to specific serine residues.