Hsp90 Is Essential for Chl1-Mediated Chromosome Segregation and Sister Chromatid Cohesion

Khurana, Nidhi; Bakshi, Sayan; Tabassum, Wahida; Bhattacharyya, Mrinal Kanti; Bhattacharyya, Sunanda

doi:10.1128/msphere.00225-18

Cited by 6 publications

(10 citation statements)

References 39 publications

(46 reference statements)

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“…While there is a paucity of evidence that physically links Eco1 to Hsp82, it remains formally possible that Hsp82 promotes rDNA hypercondensation through Eco1 acetylation of cohesin subunits. In contrast to reports that Hsp82 promotes sister chromatid cohesion through stabilization of Chl1 DNA helicase (Khurana et al, 2018), which in turn promotes both Scc2 and cohesin binding to DNA (Skibbens, 2004; Rudra and Skibbens, 2012; Shen and Skibbens, 2017b; Mayer et al, 2004; Xu et al, 2007; Borges et al, 2013; Samora et al, 2016), we find no evidence in the current study that Chl1 (or changes in cohesin/condensin dynamics) adversely impacts rDNA hypercondensation. Future studies will be required to ascertain the extent to which, histone, cohesin and/or condensin modifications promote hyperthermic-induced rDNA hypercondensation in an Hsp90-dependent manner (Figure 7).…”

Section: Discussioncontrasting

confidence: 99%

“…We validated GA-dependent Hsp90 inhibition on the Hsp90 client protein Chl1, a DNA helicase that promotes Scc2/cohesin deposition onto DNA (Supp. Figure 4; Skibbens, 2004; Khurana et al, 2018; Tahbaz et al, 2001). In combination, these results provide intriguing evidence that Hsp90 proteins may play ATP-independent ‘holding’ activities that are critical for rDNA responses to thermic stress.…”

Section: Resultsmentioning

confidence: 98%

“…Hsp90 family members exhibit receptor/kinase signal transduction activities and are well-established ATP-dependent foldases that promote protein maturation and thermic tolerance by ensuring proper folding of client proteins (Khurana et al, 2018; Morán Luengo et al, 2019; Genest et al, 2019). In addition, however, Hsp90 family members also exhibit ‘holdase’ functions independent of ATP binding/hydrolysis that include structural or scaffolding roles (Genest et al, 2019; Hoter et al, 2018; Csermely et al, 1998).…”

Section: Resultsmentioning

confidence: 99%

“…Here, we consider several possibilities regarding the mechanism through which HSP/C impact thermic-induced rDNA hypercondensation. Given the well-established role for HSP/C in stabilizing or refolding client proteins (Khurana et al, 2018; Morán Luengo et al, 2019; Genest et al, 2019), one plausible mode of action is through stabilization of an as yet undefined thermic-sensitive client protein required for rDNA hypercondensation. This client is unlikely to include cohesin or condensin, given that thermic stresses in HSP/C mutant cells result in increased rDNA axial loop lengths but not loss of either loop morphology (loops transitioning to puffs) or sister chromatid cohesion (one loop transitioning to two loops) (Shen and Skibbens, 2017a; Matos-Perdomo and Machín, 2018a).…”

Section: Discussionmentioning

confidence: 99%

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Promotion of hyperthermic-induced rDNA hypercondensation inSaccharomyces cerevisiae

Shen

Skibbens

2019

Preprint

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Ribosome biogenesis is tightly regulated through stress-sensing pathways that impact genome stability, aging and senescence. In Saccharomyces cerevisiae, ribosomal RNAs are transcribed from rDNA located on the right arm of chromosome XII. Numerous studies reveal that rDNA decondenses into a puff-like structure during interphase and condenses into a tight loop-like structure during mitosis. Intriguingly, a novel and additional mechanism of increased mitotic rDNA compaction (termed hypercondensation) was recently discovered that occurs in response to temperature stress (hyperthermic-induced) and is rapidly reversible. Here, we report that neither changes in condensin nor cohesin binding dynamics appear to play a critical role in hyperthermic-induced rDNA hypercondensation – differentiating this architectural state from normal mitotic condensation (requiring cohesins and condensins) and the premature condensation (requiring condensins) that occurs during interphase in response to nutrient starvation. A candidate genetic approach revealed that deletion of either Hsp82 or Hsc82 (Hsp90 heat shock paralogs) result in significantly reduced hyperthermic-induced rDNA hypercondensation. Intriguingly, Hsp inhibitors do not impact rDNA hypercondensation. In combination, these findings suggest that Hsp90 either stabilizes client proteins, which are sensitive to very transient thermic challenges, or directly promotes rDNA hypercondensation during preanaphase. Our findings further reveal that the high mobility group protein Hmo1 is a negative regulator of mitotic rDNA condensation, distinct from its role in promoting premature-condensation of rDNA during interphase upon nutrient starvation.

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Section: Discussioncontrasting

confidence: 99%

Section: Resultsmentioning

confidence: 98%

Section: Resultsmentioning

confidence: 99%

Section: Discussionmentioning

confidence: 99%

See 2 more Smart Citations

Promotion of hyperthermic-induced rDNA hypercondensation inSaccharomyces cerevisiae

Shen

Skibbens

2019

Preprint

View full text Add to dashboard Cite

show abstract

“…Hsp90 family members exhibit receptor/kinase signal transduction activities and are well-established ATP-dependent foldases that promote protein maturation and thermic tolerance by ensuring proper folding of client proteins (Khurana et al 2018;Morán Luengo et al 2019;Genest et al 2019). In addition, however, Hsp90 family members also exhibit "holdase" functions independent of ATP binding/hydrolysis that include structural or scaffolding roles (Csermely et al 1998;Hoter et al 2018;Genest et al 2019).…”

Section: Hsp90 Mutants Are Defective In Hyperthermic-induced Rdna Hypmentioning

confidence: 99%

Promotion of Hyperthermic-Induced rDNA Hypercondensation in Saccharomyces cerevisiae

Shen

Skibbens

2020

Genetics

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Ribosome biogenesis is tightly regulated through stress-sensing pathways that impact genome stability, aging and senescence. In Saccharomyces cerevisiae, ribosomal RNAs are transcribed from rDNA located on the right arm of chromosome XII. Numerous studies reveal that rDNA decondenses into a puff-like structure during interphase, and condenses into a tight loop-like structure during mitosis. Intriguingly, a novel and additional mechanism of increased mitotic rDNA compaction (termed hypercondensation) was recently discovered that occurs in response to temperature stress (hyperthermic-induced) and is rapidly reversible. Here, we report that neither changes in condensin binding or release of DNA during mitosis, nor mutation of factors that regulate cohesin binding and release, appear to play a critical role in hyperthermic-induced rDNA hypercondensation. A candidate genetic approach revealed that deletion of either HSP82 or HSC82 (Hsp90 encoding heat shock paralogs) result in significantly reduced hyperthermic-induced rDNA hypercondensation. Intriguingly, Hsp inhibitors do not impact rDNA hypercondensation. In combination, these findings suggest that Hsp90 either stabilizes client proteins, which are sensitive to very transient thermic challenges, or directly promotes rDNA hypercondensation during preanaphase. Our findings further reveal that the high mobility group protein Hmo1 is a negative regulator of mitotic rDNA condensation, distinct from its role in promoting premature condensation of rDNA during interphase upon nutrient starvation.

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Functional connections between cell cycle and proteostasis in the regulation of Candida albicans morphogenesis

et al. 2021

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SUMMARY Morphological plasticity is a key virulence trait for many fungal pathogens. For the opportunistic fungal pathogen Candida albicans , transitions among yeast, pseudohyphal, and hyphal forms are critical for virulence, because the morphotypes play distinct roles in the infection process. C. albicans morphogenesis is induced in response to many host-relevant conditions and is regulated by complex signaling pathways and cellular processes. Perturbation of either cell-cycle progression or protein homeostasis induces C. albicans filamentation, demonstrating that these processes play a key role in morphogenetic control. Regulators such as cyclin-dependent kinases, checkpoint proteins, the proteasome, the heat shock protein Hsp90, and the heat shock transcription factor Hsf1 all influence morphogenesis, often through interconnected effects on the cell cycle and proteostasis. This review highlights the major cell-cycle and proteostasis regulators that modulate morphogenesis and discusses how these two processes intersect to regulate this key virulence trait.

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Hsp90 Is Essential for Chl1-Mediated Chromosome Segregation and Sister Chromatid Cohesion

Cited by 6 publications

References 39 publications

Promotion of hyperthermic-induced rDNA hypercondensation inSaccharomyces cerevisiae

Promotion of hyperthermic-induced rDNA hypercondensation inSaccharomyces cerevisiae

Promotion of Hyperthermic-Induced rDNA Hypercondensation in Saccharomyces cerevisiae

Functional connections between cell cycle and proteostasis in the regulation of Candida albicans morphogenesis

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