Sarah Pfennig scite author profile

Sarah Pfennig

3Publications

19Citation Statements Received

179Citation Statements Given

How they've been cited

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175

Affiliations

Neurosciences Institute, New York University, Neuroscience Institute

Publications

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PRC1 sustains the integrity of neural fate in the absence of PRC2 function

Sawai

Pfennig

Bulajić

et al. 2022

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Polycomb repressive complexes (PRCs) 1 and 2 maintain stable cellular memories of early fate decisions by establishing heritable patterns of gene repression. PRCs repress transcription through histone modifications and chromatin compaction, but their roles in neuronal subtype diversification are poorly defined. We found that PRC1 is essential for the specification of segmentally-restricted spinal motor neuron (MN) subtypes, while PRC2 activity is dispensable to maintain MN positional identities during terminal differentiation. Mutation of the core PRC1 component Ring1 in mice leads to increased chromatin accessibility and ectopic expression of a broad variety of fates determinants, including Hox transcription factors, while neuronal class-specific features are maintained. Loss of MN subtype identities in Ring1 mutants is due to the suppression of Hox-dependent specification programs by derepressed Hox13 paralogs (Hoxa13, Hoxb13, Hoxc13, Hoxd13). These results indicate that PRC1 can function in the absence of de novo PRC2-dependent histone methylation to maintain chromatin topology and postmitotic neuronal fate.

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PRC1 Sustains the Memory of Neuronal Fate Independent of PRC2 Function

Dasen

Sawai

Pfennig

et al. 2021

Preprint

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Polycomb repressive complexes (PRCs) 1 and 2 maintain stable cellular memories of early fate decisions by establishing heritable patterns of gene repression. PRCs repress transcription through histone modifications and chromatin compaction, but their roles in neuronal subtype diversification are poorly defined. We unexpectedly found that PRC2 is dispensable to preserve the morphogen-induced positional fates of spinal motor neurons (MNs), while PRC1 is essential for the specification of segmentally-restricted subtypes. Mutation of the core PRC1 component Ring1 in mice leads to increased chromatin accessibility and ectopic expression of a broad variety of fates determinants, including Hox transcription factors, while neuronal class-specific features are maintained. Loss of MN subtype identities in Ring1 mutants is due to the suppression of Hox networks by derepressed caudal Hox genes. These results indicate that PRC1 can function independently of de novo PRC2-dependent histone methylation to maintain chromatin topology and transcriptional memory at the time of neuronal differentiation.

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Author response: PRC1 sustains the integrity of neural fate in the absence of PRC2 function

Sawai

Pfennig

Bulajić

et al. 2021

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Sarah Pfennig

PRC1 sustains the integrity of neural fate in the absence of PRC2 function

PRC1 Sustains the Memory of Neuronal Fate Independent of PRC2 Function

Author response: PRC1 sustains the integrity of neural fate in the absence of PRC2 function

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