Visualizing the metazoan proliferation-terminal differentiation decision<i>in vivo</i>

Kohrman, Abraham; Adikes, Rebecca C.; Martinez, Michael A Q; Palmisano, Nicholas J.; Smith, Jayson J.; Medwig-Kinney, Taylor N.; Min, Mingwei; Sallee, Maria D.; Ahmed, Ononnah B; Kim, Nuri; Liu, Simeiyun; Morabito, Robert D; Weeks, Nicholas; Zhao, Qinyun; Zhang, Wan; Feldman, Jessica L.; Barkoulas, Michalis; Pani, Ariel M.; Spencer, Steven J.; Martin, Benjamin L.; Matus, David Q.

doi:10.1101/2019.12.18.881888

Cited by 2 publications

(10 citation statements)

References 149 publications

(181 reference statements)

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“…Interestingly, 27.9% (12/43) of animals treated with swsn-4(RNAi) were absent of SMs on either the left or the right side, whereas 100% (30/30) control animals had SMs on both sides, which may indicate a defect in either specification or migration of SMs ( Fig S5 B ). We then employed a cyclin-dependent kinase (CDK) sensor, which uses a fragment of mammalian DNA Helicase B (DHB) fused to two copies of mKate2 (35, 67), to quantify cell cycle state. In cells with low CDK activity that are quiescent or post-mitotic, the ratiometric CDK sensor is strongly nuclear localized (35,66,67).…”

Section: Resultsmentioning

confidence: 99%

“…We then employed a cyclin-dependent kinase (CDK) sensor, which uses a fragment of mammalian DNA Helicase B (DHB) fused to two copies of mKate2 (35, 67), to quantify cell cycle state. In cells with low CDK activity that are quiescent or post-mitotic, the ratiometric CDK sensor is strongly nuclear localized (35,66,67). In cycling cells with increasing CDK activity, the CDK sensor progressively translocates from the nucleus to the cytosoplasm, with a ratio approaching 1.0 in S phase and >1 in cells in G 2 (35).…”

Section: Resultsmentioning

confidence: 99%

“…This finding parallels similar studies in cancer (30–33) and C. elegans mesoblast development (34). Examination using a DNA Helicase B (DHB)-based CDK activity sensor (35) revealed assembly-specific contributions to AC invasion: whereas BAF promotes AC invasion in a cell cycle-dependent manner, PBAF contributes to invasion in a cell cycle-independent manner. Finally, we utilized the auxin-inducible degron (AID) system combined with PBAF RNAi to achieve strong PBAF subunit depletion in the AC, which resulted in loss of both AC invasion and adhesion to the BM.…”

Section: Introductionmentioning

confidence: 99%

“…We generated two anti-GFP nanobody constructs, using conserved cis-regulatory elements from the cdh-3 and egl-43 promoters (22,24,38,65,66) and introduced them to a strain containing an endogenous GFPtagged allele of swsn-4 as well as background AC and BM reporters (Fig 3 (35,67), to quantify cell cycle state. In cells with low CDK activity that are quiescent or post-mitotic, the ratiometric CDK sensor is strongly nuclear localized (35,66,67). In cycling cells with increasing CDK activity, the CDK sensor progressively translocates from the nucleus to the cytosoplasm, with a ratio approaching 1.0 in S phase and >1 in cells in G 2 (35).…”

mentioning

confidence: 99%

“…In cells with low CDK activity that are quiescent or post-mitotic, the ratiometric CDK sensor is strongly nuclear localized (35,66,67). In cycling cells with increasing CDK activity, the CDK sensor progressively translocates from the nucleus to the cytosoplasm, with a ratio approaching 1.0 in S phase and >1 in cells in G 2 (35). Altogether, our data demonstrated that in the AC, the SWSN-4 core ATPase of the SWI/SNF complex contributes to invasion in a dose-dependent manner: moderate loss of expression produced non-invasive single ACs while extreme loss of expression led to a non-invasive hyperproliferative state.…”

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confidence: 99%

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The SWI/SNF chromatin remodeling assemblies BAF and PBAF differentially regulate cell cycle exit and cellular invasionin vivo

Smith

Xiao

et al. 2021

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Chromatin remodeling complexes, such as the SWItching defective/Sucrose Non-Fermenting (SWI/SNF) ATP-dependent chromatin remodeling complex, coordinate metazoan development through broad regulation of chromatin accessibility and transcription, ensuring normal cell cycle control and cellular differentiation in a lineage-specific and temporally restricted manner. Mutations in subunits of chromatin regulating factors are associated with a variety of diseases and cancer metastasis co-opts cellular invasion found in healthy cells during development. Here we utilize Caenorhabditis elegans anchor cell (AC) invasion as an in vivo model to identify the suite of chromatin and chromatin regulating factors (CRFs) that promote cellular invasiveness. We demonstrate that the SWI/SNF ATP-dependent chromatin remodeling complex is a critical regulator of AC invasion, with pleiotropic effects on both G0/G1 cell cycle arrest and activation of invasive machinery. Using targeted protein degradation and RNA interference (RNAi), we show that SWI/SNF contributes to AC invasion in a dose-dependent fashion, with lower levels of activity in the AC corresponding to aberrant cell cycle entry and increased loss of invasion. Finally, we implicate the SWI/SNF BAF assembly in the regulation of the cell cycle, whereas our data suggests that the SWI/SNF PBAF assembly promotes AC attachment to the basement membrane (BM) and promotes the activation of the invasive machinery. Together these findings demonstrate that the SWI/SNF complex is necessary for two essential components of AC invasion: arresting cell cycle progression and remodeling the BM. The work here provides valuable single-cell mechanistic insight into the contributions of SWI/SNF assembly and subunit-specific disruptions to tumorigenesis and cancer metastasis.

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Section: Resultsmentioning

confidence: 99%

Section: Resultsmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

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confidence: 99%

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confidence: 99%

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The SWI/SNF chromatin remodeling assemblies BAF and PBAF differentially regulate cell cycle exit and cellular invasionin vivo

Smith

Xiao

et al. 2021

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Stable integration of an optimized inducible promoter system enables spatiotemporal control of gene expression throughout avian development

Chu

Nguyen

Smith

et al. 2020

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StatementWe have designed an optimized and integrating inducible-promoter system to control the timing, spatial domains, and levels of gene misexpression throughout avian development. AbstractPrecisely altering gene expression is critical for understanding molecular processes of embryogenesis. Although some tools exist for transgene misexpression in developing chick embryos, we have refined and advanced them by simplifying and optimizing constructs for spatiotemporal control. To maintain expression over the entire course of embryonic development we use an enhanced piggyBac transposon system that efficiently integrates sequences into the host genome. We also incorporate a DNA targeting sequence to direct plasmid translocation into the nucleus and a D4Z4 insulator sequence to prevent epigenetic silencing. We designed these constructs to minimize their size and maximize cellular uptake, and to simplify usage by placing all of the integrating sequences on a single plasmid. Following electroporation of stage HH8.5 embryos, our tetracycline-inducible promoter construct produces robust transgene expression in the presence of doxycycline at any point during embryonic development in ovo or in culture. Moreover, expression levels can be modulated by titrating doxycycline concentrations and spatial control can be achieved using beads or gels. Thus, we have generated a novel, sensitive, tunable, and stable inducible-promoter system for highresolution gene manipulation in vivo. (2016). Improving brightness and photostability of green and red fluorescent proteins for live cell imaging and FRET reporting. Sci Rep 6, 20889. Bellairs, R. and Osmond, M. (2005). The atlas of chick development (2nd edn). Amsterdam ; Boston ; London: Elsevier. Benjamini, Y. and Hochberg, Y. (1995). Controlling the false discovery rate: a practical and powerful approach to multiple testing. Journal of the Royal statistical society: series B (Methodological) 57, 289-300. Betancur, P., Bronner-Fraser, M. and Sauka-Spengler, T. (2010). Assembling neural crest regulatory circuits into a gene regulatory network. Annual review of cell and developmental biology 26, 581-603.

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Visualizing the metazoan proliferation-terminal differentiation decisionin vivo

Cited by 2 publications

References 149 publications

The SWI/SNF chromatin remodeling assemblies BAF and PBAF differentially regulate cell cycle exit and cellular invasionin vivo

The SWI/SNF chromatin remodeling assemblies BAF and PBAF differentially regulate cell cycle exit and cellular invasionin vivo

Stable integration of an optimized inducible promoter system enables spatiotemporal control of gene expression throughout avian development

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