Your search keyword '"Shum, Eleen Y"' showing total 3 results

1. The Homeobox Transcription Factor RHOX10 Drives Mouse Spermatogonial Stem Cell Establishment

Author

Song, Hye-Won, Bettegowda, Anilkumar, Lake, Blue B., Zhao, Adrienne H., Skarbrevik, David, Babajanian, Eric, Sukhwani, Meena, Shum, Eleen Y., Phan, Mimi H., Plank, Terra-Dawn M., Richardson, Marcy E., Ramaiah, Madhuvanthi, Sridhar, Vaishnavi, de Rooij, Dirk G., Orwig, Kyle E., Zhang, Kun, and Wilkinson, Miles F.

Abstract

The developmental origins of most adult stem cells are poorly understood. Here, we report the identification of a transcription factor—RHOX10—critical for the initial establishment of spermatogonial stem cells (SSCs). Conditional loss of the entire 33-gene X-linked homeobox gene cluster that includes Rhox10causes progressive spermatogenic decline, a phenotype indistinguishable from that caused by loss of only Rhox10. We demonstrate that this phenotype results from dramatically reduced SSC generation. By using a battery of approaches, including single-cell-RNA sequencing (scRNA-seq) analysis, we show that Rhox10drives SSC generation by promoting pro-spermatogonia differentiation. Rhox10also regulates batteries of migration genes and promotes the migration of pro-spermatogonia into the SSC niche. The identification of an X-linked homeobox gene that drives the initial generation of SSCs has implications for the evolution of X-linked gene clusters and sheds light on regulatory mechanisms influencing adult stem cell generation in general.

Published

2016

2. Posttranscriptional Control of the Stem Cell and Neurogenic Programs by the Nonsense-Mediated RNA Decay Pathway

Author

Lou, Chih H., Shao, Ada, Shum, Eleen Y., Espinoza, Josh L., Huang, Lulu, Karam, Rachid, and Wilkinson, Miles F.

Abstract

The mechanisms dictating whether a cell proliferates or differentiates have undergone intense scrutiny, but they remain poorly understood. Here, we report that UPF1, a central component in the nonsense-mediated RNA decay (NMD) pathway, plays a key role in this decision by promoting the proliferative, undifferentiated cell state. UPF1 acts, in part, by destabilizing the NMD substrate encoding the TGF-β inhibitor SMAD7 and stimulating TGF-β signaling. UPF1 also promotes the decay of mRNAs encoding many other proteins that oppose the proliferative, undifferentiated cell state. Neural differentiation is triggered when NMD is downregulated by neurally expressed microRNAs (miRNAs). This UPF1-miRNA circuitry is highly conserved and harbors negative feedback loops that act as a molecular switch. Our results suggest that the NMD pathway collaborates with the TGF-β signaling pathway to lock in the stem-like state, a cellular state that is stably reversed when neural differentiation signals that induce NMD-repressive miRNAs are received.

Published

2014

3. Next-Generation Digital Polymerase Chain Reaction: High-Dynamic-Range Single-Molecule DNA Counting via Ultrapartitioning

Author

Shum, Eleen Y., Lai, Janice H., Li, Sixing, Lee, Haeun G., Soliman, Jesse, Raol, Vedant K., Lee, Cavina K., Fodor, Stephen P.A., and Fan, H. Christina

Abstract

Digital PCR (dPCR) was first conceived for single-molecule quantitation. However, current dPCR systems often require DNA templates to share partitions due to limited partitioning capacities. Here, we introduce UltraPCR, a next-generation dPCR system where DNA counting is performed in a single-molecule regimen through a 6-log dynamic range using a swift and parallelized workflow. Each UltraPCR reaction is divided into >30 million partitions without microfluidics to achieve single template occupancy. Combined with a unique emulsion chemistry, partitions are optically clear, enabling the use of a three-dimensional imaging technique to rapidly detect DNA-positive partitions. Single-molecule occupancy also allows for more straightforward multiplex assay development due to the absence of partition-specific competition. As a proof of concept, we developed a 222-plex UltraPCR assay and demonstrated its potential use as a rapid, low-cost screening assay for noninvasive prenatal testing for as low as 4% trisomy fraction samples with high precision, accuracy, and reproducibility.

Published

2022