A Visual Screen of Protein Localization during Sporulation Identifies New Components of Prospore Membrane-Associated Complexes in Budding Yeast

Lam, Chien; Santore, Ethan; Lavoie, Elizabeth M.; Needleman, Leor; Fiacco, Nicholas; Kim, Carey; Neiman, Aaron M.

doi:10.1128/ec.00333-13

Cited by 28 publications

(39 citation statements)

References 52 publications

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“…In contrast, association with Mip6 might lead to translation primarily within the spore cytoplasm. Consistent with this, SPS4, which is most clearly dependent on PES4 and independent of MIP6 (Table 2), is found primarily on lipid droplets that are in the ascal cytoplasm (20,26), but whether this is related to localization of the transcript requires further investigation.…”

Section: Discussionmentioning

confidence: 56%

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Predicted RNA Binding Proteins Pes4 and Mip6 Regulate mRNA Levels, Translation, and Localization during Sporulation in Budding Yeast

Jin

Zhang

Sternglanz

et al. 2017

Molecular and Cellular Biology

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In response to starvation, diploid cells of undergo meiosis and form haploid spores, a process collectively referred to as sporulation. The differentiation into spores requires extensive changes in gene expression. The transcriptional activator Ndt80 is a central regulator of this process, which controls many genes essential for sporulation. Ndt80 induces ∼300 genes coordinately during meiotic prophase, but different mRNAs within the regulon are translated at different times during sporulation. The protein kinase Ime2 and RNA binding protein Rim4 are general regulators of meiotic translational delay, but how differential timing of individual transcripts is achieved was not known. This report describes the characterization of two related -induced genes, and , encoding predicted RNA binding proteins. These genes are necessary to regulate the steady-state expression, translational timing, and localization of a set of mRNAs that are transcribed by but not translated until the end of meiosis II. Mutations in the predicted RNA binding domains within alter the stability of target mRNAs. and affect only a small portion of the regulon, indicating that they act as modulators of the general Ime2/Rim4 pathway for specific transcripts.

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Section: Discussionmentioning

confidence: 56%

“…Pes4 and Mip6 display distinct protein localizations. Previous studies failed to detect a signal for either Pes4 or Mip6 in sporulating cells when the proteins were tagged on the C terminus with a single copy of GFP (26). The Pes4 and Mip6 proteins were observed, however, when the proteins were C-terminally tagged with three copies of GFP (3ϫGFP).…”

Section: Figmentioning

confidence: 98%

Predicted RNA Binding Proteins Pes4 and Mip6 Regulate mRNA Levels, Translation, and Localization during Sporulation in Budding Yeast

Jin

Zhang

Sternglanz

et al. 2017

Molecular and Cellular Biology

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“…The MPs serve as nucleation platforms and anchors for de novo formation of the prospore membranes (PSM), which derive from fusion of secretory vesicles and grow around the nuclear lobes and parts of the cytoplasm (Neiman 1998;Nakanishi et al 2006;Mathieson et al 2010). A protein coat consisting of Ssp1, Ady3, Irc10, and Don1 covers the leading edge of the growing PSMs (Knop and Strasser 2000;Nickas and Neiman 2002;Lam et al 2014). The protein Ssp1 is essential for PSM formation; it is required for localization of the other proteins to the leading edge and to maintain the opening of the PSMs until the end of meiosis II (Moreno-Borchart et al 2001;Lam et al 2014).…”

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confidence: 99%

“…A protein coat consisting of Ssp1, Ady3, Irc10, and Don1 covers the leading edge of the growing PSMs (Knop and Strasser 2000;Nickas and Neiman 2002;Lam et al 2014). The protein Ssp1 is essential for PSM formation; it is required for localization of the other proteins to the leading edge and to maintain the opening of the PSMs until the end of meiosis II (Moreno-Borchart et al 2001;Lam et al 2014). The cytokinetic event of PSM closure occurs after spindle breakdown and depends on the removal of Ssp1 from the leading edge (Maier et al 2007;Diamond et al 2009;Paulissen et al 2016).…”

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confidence: 99%

The Mitotic Exit Network Regulates Spindle Pole Body Selection During Sporulation of Saccharomyces cerevisiae

et al. 2017

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Age-based inheritance of centrosomes in eukaryotic cells is associated with faithful chromosome distribution in asymmetric cell divisions. During ascospore formation, such an inheritance mechanism targets the yeast centrosome equivalents, the spindle pole bodies (SPBs) at meiosis II onset. Decreased nutrient availability causes initiation of spore formation at only the younger SPBs and their associated genomes. This mechanism ensures encapsulation of nonsister genomes, which preserves genetic diversity and provides a fitness advantage at the population level. Here, by usage of an enhanced system for sporulation-induced protein depletion, we demonstrate that the core mitotic exit network (MEN) is involved in age-based SPB selection. Moreover, efficient genome inheritance requires Dbf2/20-Mob1 during a late step in spore maturation. We provide evidence that the meiotic functions of the MEN are more complex than previously thought. In contrast to mitosis, completion of the meiotic divisions does not strictly rely on the MEN whereas its activity is required at different time points during spore development. This is reminiscent of vegetative MEN functions in spindle polarity establishment, mitotic exit, and cytokinesis. In summary, our investigation contributes to the understanding of age-based SPB inheritance during sporulation of and provides general insights on network plasticity in the context of a specialized developmental program. Moreover, the improved system for a developmental-specific tool to induce protein depletion will be useful in other biological contexts.

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“…The leading edge protein complex (LEP), composed of Don1, Ady3, Irc10, and Ssp1, is found at the growing end of the PSM and is required for proper growth and closure of the PSM (Knop and Strasser 2000;Moreno-Borchart et al 2001;Nickas and Neiman 2002;Lam et al 2014). Ssp1 is the most critical component of the LEP, required for the leading edge localization of the other LEP members (Nag et al 1997;Moreno-Borchart et al 2001).…”

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confidence: 99%

Timely Closure of the Prospore Membrane Requires SPS1 and SPO77 in Saccharomyces cerevisiae

et al. 2016

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During sporulation in Saccharomyces cerevisiae, a double lipid bilayer called the prospore membrane is formed de novo, growing around each meiotic nucleus and ultimately closing to create four new cells within the mother cell. Here we show that SPS1, which encodes a kinase belonging to the germinal center kinase III family, is involved in prospore membrane development and is required for prospore membrane closure. We find that SPS1 genetically interacts with SPO77 and see that loss of either gene disrupts prospore membrane closure in a similar fashion. Specifically, cells lacking SPS1 and SPO77 produce hyperelongated prospore membranes from which the leading edge protein complex is not removed from the prospore membrane in a timely fashion. The SPS1/ SPO77 pathway is required for the proper phosphorylation and stability of Ssp1, a member of the leading edge protein complex that is removed and degraded when the prospore membrane closes. Genetic dissection of prospore membrane closure finds SPS1 and SPO77 act in parallel to a previously described pathway of prospore membrane closure that involves AMA1, an activator of the meiotic anaphase promoting complex.KEYWORDS prospore membrane; meiotic exit; anaphase promoting complex; sporulation; cytokinesis; germinal center kinase B IOLOGICAL membranes provide a barrier for inhibiting the flow of materials between a cell and its surroundings and for compartmentalizing the contents of the various organelles within a cell. The size and shape of membranes are central to their functions. Membranes are essential for many fundamental cellular processes including ion balance, energy generation, and secretion. In cell division, membrane dynamics are particularly important, where they act to segregate the contents of the cellular progeny.The process of cell division differs among cells. Most commonly, animal cells divide through a mechanism requiring the assembly of an actin-based contractile ring at the division site (reviewed in Green et al. 2012). This actomyosin ring contracts and matures, ultimately leading to scission of the membrane necks mediated by the ESCRTIII (endosomal sorting complex required for transport III) complex. However, other variations of cytokinesis occur: cellularization during early Drosophila embryogenesis, which requires the growth of membranes around the nuclei before the contractile event (Lee and Harris 2014) and cell division in plants, which requires the secretion of vesicles to the division plane to form the phragmoplast, which will eventually separate the two daughter cells (reviewed in Jürgens 2005). Actin is not always involved in cytokinesis; although prokaryotic cells have actin-like filaments (reviewed in Carballido-López 2006), these filaments are not used for cytokinesis (Pollard and Wu 2010). Similarly, cytokinesis in Trypanosoma brucei (a bikont eukaryote) does not require actin but seems to utilize microtubules (Wheeler et al. 2013). In the budding yeast Saccharomyces cerevisiae, an actin-based contractile ring plays a role in ...

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A Visual Screen of Protein Localization during Sporulation Identifies New Components of Prospore Membrane-Associated Complexes in Budding Yeast

Cited by 28 publications

References 52 publications

Predicted RNA Binding Proteins Pes4 and Mip6 Regulate mRNA Levels, Translation, and Localization during Sporulation in Budding Yeast

Predicted RNA Binding Proteins Pes4 and Mip6 Regulate mRNA Levels, Translation, and Localization during Sporulation in Budding Yeast

The Mitotic Exit Network Regulates Spindle Pole Body Selection During Sporulation of Saccharomyces cerevisiae

Timely Closure of the Prospore Membrane Requires SPS1 and SPO77 in Saccharomyces cerevisiae

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