Mechanics of MTOC clustering and spindle positioning in budding yeast <i>Cryptococcus neoformans</i>

Chatterjee, Saptarshi; Som, Subhendu; Varshney, Neha; Satyadev, Pvs; Sanyal, Kaustuv; Paul, Raja

doi:10.1101/690651

Cited by 1 publication

(2 citation statements)

References 104 publications

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“…Recent studies in C. neoformans have shown that the spatial distribution of dynein and Bim1 plays an essential role in nuclear migration (Varshney et al, 2019). As the cell cycle progresses, a localized dynein patch is formed in the daughter cortex along the axis of symmetry, which pulls the nucleus inside the daughter bud (Chatterjee et al, 2021). In our transcriptomic data, we observe that BIM1 transcript was at higher levels in slu7kd when compared wildtype while DYN1 transcript levels were unaffected.…”

Section: Discussionmentioning

confidence: 99%

“…Recent biochemical and cryo–EM studies have reported the role of LIS1/Pac1 in dynein regulation in S. cerevisiae (Markus et al, 2011; Huang et al, 2012; DeSantis et al, 2017). Studies in Cryptococcus neoformans have demonstrated the mechanics of nuclear migration and spindle positioning by time–lapse live cell imaging and quantitative modelling (Kozubowski et al, 2013; Varshney et al, 2019; Chatterjee et al, 2021). Transcriptional profiling of C. neoformans cell cycle revealed periodic changes in the expression of 1134 out of 6182 transcripts tested (Kelliher et al, 2016).…”

Section: Introductionmentioning

confidence: 99%

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Cryptococcus neoformansSlu7 ensures nuclear positioning during mitotic progression through RNA splicing

Krishnan,

Negi,

Peesapati

et al. 2023

Preprint

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The position of the nucleus before it divides during mitosis is variable in different budding yeasts. Studies in the pathogenic intron-rich fungusCryptococcus neoformansreveal that the nucleus moves entirely into the daughter bud before its division. Here, we report functions of a zinc finger motif containing spliceosome proteinC. neoformansSlu7 (CnSlu7) in cell cycle progression. The budding yeast and fission yeast homologs of Slu7 have predominant roles for intron 3’ splice site definition during pre-mRNA splicing. Using a conditional knockdown strategy, we show CnSlu7 is an essential factor for viability and is required for efficient cell cycle progression with major role during mitosis. Aberrant nuclear migration, including improper positioning of the nucleus as well as the spindle, were frequently observed in cells depleted of CnSlu7. However, cell cycle delays observed due to Slu7 depletion did not activate the Mad2-dependent spindle assembly checkpoint (SAC). Mining of the global transcriptome changes in the Slu7 knockdown strain identified downregulation of transcripts encoding several cell cycle regulators and cytoskeletal factors for nuclear migration, and the splicing of specific introns of these genes was CnSlu7 dependent. To test the importance of splicing activity of CnSlu7 on nuclear migration, we complemented Slu7 knockdown cells with an intron lessPAC1minigene and demonstrated that the nuclear migration defects were significantly rescued. These findings show that CnSlu7 regulates the functions of diverse cell cycle regulators and cytoskeletal components, ensuring timely cell cycle transitions and nuclear division during mitosis.

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Section: Discussionmentioning

confidence: 99%