Project description:The polyadenylation of mRNA is pivotal for mRNA stability and efficient mRNA translation. The length of poly(A) tail is dynamically changed under various physiological conditions; however, the functions and mechanisms of aberrant poly(A) length control in cancers remain poorly understood. Here we uncovered the aberrant lengthening of poly(A) tail and particularly upregulated expression of poly(A) polymerase alpha (PAPOLA) in acute myeloid leukemia (AML), and the elevated PAPOLA expression significantly correlated with unfavorable AML outcomes. We further demonstrated the critical oncogenic functions of PAPOLA-mediated poly(A) lengthening in promoting AML leukemogenesis and leukemia stem cell self-renewal using human primary AML samples, AML cells and various mouse leukemogenesis models. Mechanistically, we identified GSTM2 as a key downstream target of PAPOLA that regulated metabolic reprogramming through the HNE-DLD axis to promote AML initiation and progression. Moreover, PAPOLA inhibitor cordycepin effectively blocked metabolic reprogramming and AML leukemogenesis in vivo. Overall, our study uncovers the novel functional link between aberrant poly(A) lengthening and cellular metabolic reprogramming in AML, and provides a molecular basis for development of an effective therapeutic strategy for AML patients.

Project description:The polyadenylation of mRNA is pivotal for mRNA stability and efficient mRNA translation. The length of poly(A) tail is dynamically changed under various physiological conditions; however, the functions and mechanisms of aberrant poly(A) length control in cancers remain poorly understood. Here we uncovered the aberrant lengthening of poly(A) tail and particularly upregulated expression of poly(A) polymerase alpha (PAPOLA) in acute myeloid leukemia (AML), and the elevated PAPOLA expression significantly correlated with unfavorable AML outcomes. We further demonstrated the critical oncogenic functions of PAPOLA-mediated poly(A) lengthening in promoting AML leukemogenesis and leukemia stem cell self-renewal using human primary AML samples, AML cells and various mouse leukemogenesis models. Mechanistically, we identified GSTM2 as a key downstream target of PAPOLA that regulated metabolic reprogramming through the HNE-DLD axis to promote AML initiation and progression. Moreover, PAPOLA inhibitor cordycepin effectively blocked metabolic reprogramming and AML leukemogenesis in vivo. Overall, our study uncovers the novel functional link between aberrant poly(A) lengthening and cellular metabolic reprogramming in AML, and provides a molecular basis for development of an effective therapeutic strategy for AML patients.

Project description:The polyadenylation of mRNA is pivotal for mRNA stability and efficient mRNA translation. The length of poly(A) tail is dynamically changed under various physiological conditions; however, the functions and mechanisms of aberrant poly(A) length control in cancers remain poorly understood. Here we uncovered the aberrant lengthening of poly(A) tail and particularly upregulated expression of poly(A) polymerase alpha (PAPOLA) in acute myeloid leukemia (AML), and the elevated PAPOLA expression significantly correlated with unfavorable AML outcomes. We further demonstrated the critical oncogenic functions of PAPOLA-mediated poly(A) lengthening in promoting AML leukemogenesis and leukemia stem cell self-renewal using human primary AML samples, AML cells and various mouse leukemogenesis models. Mechanistically, we identified GSTM2 as a key downstream target of PAPOLA that regulated metabolic reprogramming through the HNE-DLD axis to promote AML initiation and progression. Moreover, PAPOLA inhibitor cordycepin effectively blocked metabolic reprogramming and AML leukemogenesis in vivo. Overall, our study uncovers the novel functional link between aberrant poly(A) lengthening and cellular metabolic reprogramming in AML, and provides a molecular basis for development of an effective therapeutic strategy for AML patients.

Project description:Function and mechanism of PAPOLA-mediated poly(A) lengthening in leukemia

Project description:Function and mechanism of PAPOLA-mediated poly(A) lengthening in leukemia (mouse)

Project description:Function and mechanism of PAPOLA-mediated poly(A) lengthening in leukemia [RNA-Seq]

Project description:Function and mechanism of PAPOLA-mediated poly(A) lengthening in leukemia [RIP-Seq]

Project description:Function and mechanism of PAPOLA-mediated poly(A) lengthening in leukemia [FLAM-Seq]

Project description:In oocytes of mammals and other animals, gene regulation is mediated primarily through changes in poly(A)-tail length. Here, we introduce PAL-AI, an integrated neural network machine-learning model that accurately predicts tail-length changes in maturing oocytes of frogs and mammals. We show that PAL-AI learned known and previously unknown sequence elements and their contextual features that control poly(A)-tail length, enabling it to predict tail-length changes resulting from 3ʹ-UTR single-nucleotide substitutions. It also predicted tail-length-mediated translational changes, allowing us to nominate genes important for oocyte maturation. When comparing predicted tail-length changes in human oocytes with genomic datasets of the All of Us Research Program and gnomAD we found that genetic variants predicted to disrupt tail lengthening are under negative selection in the human population, thereby linking mRNA tail lengthening to human female fertility.

Project description:Differentiation of neural progenitor cells into mature neuronal phenotypes relies on extensive temporospatial coordination of mRNA expression to support the development of functional brain circuitry. Cleavage and polyadenylation of mRNA has tremendous regulatory capacity through the alteration of mRNA stability and modulation of microRNA (miRNA) function, however the extent of utilization in neuronal development is currently unclear. Here, we employed poly(A) tail sequencing, mRNA sequencing, ribosome profiling and small RNA sequencing to explore the functional relationship between mRNA abundance, translation, poly(A) tail length, alternative polyadenylation (APA) and miRNA expression in an in vitro model of neuronal differentiation. Differential analysis revealed a strong bias towards poly(A) tail and 3´UTR lengthening during differentiation, both of which were associated with changes in mRNA abundance but not translation. Globally, changes in miRNA expression were predominantly associated with mRNA abundance and translation, however several miRNA-mRNA pairings with potential to regulate poly(A) tail length were identified. Furthermore, 3´UTR lengthening was observed to significantly increase the inclusion of non-conserved miRNA binding sites, potentially enhancing the regulatory capacity of these molecules in mature neuronal cells. Together, our findings suggest poly(A) tail length and APA function as part of a rich post-transcriptional regulatory matrix during neuronal differentiation.