Abigail Reyes scite author profile

In Saccharomyces cerevisiae, Chs4p is required for chitin synthase III (CSIII) activity and hence for chitin synthesis. This protein is transported in vesicles in a polarized fashion independently of the other Chs proteins. Its association with membranes depends not only on prenylation, but also on its interaction with other proteins, mainly Chs3p, which is the catalytic subunit of CSIII and is able to properly direct Chs4p to the bud neck in the absence of prenylation. Chs4p is present in functionally limiting amounts and its overexpression increases Chs3p accumulation at the plasma membrane with a concomitant increase in chitin synthesis. In the absence of Chs4p, Chs3p is delivered to the plasma membrane but fails to accumulate there because it is rapidly endocytosed and accumulates in intracellular vesicles. A blockade of endocytosis stops Chs3p internalization, triggering a significant increase in chitin synthesis. This blockade is independent of Chs4p function, allowing the accumulation of Chs3p at the plasma membrane even in the chs4Δ mutant. However, the absence of Chs4p renders CSIII functionally inactive, independently of Chs3p accumulation at the plasma membrane. Chs4p thus promotes Chs3p translocation into the plasma membrane in a stable and active form. Proper CSIII turnover is maintained through the endocytic internalization of Chs3p.

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Oligomerization of the chitin synthase Chs3 is monitored at the Golgi and affects its endocytic recycling

Sacristán

Manzano-López

Reyes

et al. 2013

Molecular Microbiology

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SummaryChs3, the catalytic subunit of chitin synthase III in Saccharomyces cerevisiae, is a complex polytopic membrane protein whose plasma membrane expression is tightly controlled: export from the ER requires interaction with Chs7; exit from the Golgi is dependent on the exomer complex, and precise bud neck localization relies on endocytosis. Moreover, Chs3 is efficiently recycled from endosomes to the TGN in an AP-1-dependent manner. Here we show that the export of Chs3 requires the cargo receptor Erv14, in a step that is independent of Chs7. Chs3 oligomerized in the ER through its N-terminal cytosolic region. However, the truncated Δ126Chs3 was still exported by Erv14, but was sent back from the Golgi to the ER in a COPI-and Rer1-dependent manner. A subset of the oligomerization-deficient Chs3 proteins evaded Golgi quality control and reached the plasma membrane, where they were enzymatically active but poorly endocytosed. This resulted in high CSIII levels, but calcofluor white resistance, explained by the reduced intercalation of calcofluor white between nascent chitin fibres. Our data show that the oligomerization of Chs3 through its N-terminus is essential for proper protein trafficking and chitin synthesis and is therefore monitored intracellularly.

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Slt2 and Rim101 Contribute Independently to the Correct Assembly of the Chitin Ring at the Budding Yeast Neck in Saccharomyces cerevisiae

et al. 2009

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In Saccharomyces cerevisiae, the simultaneous absence of Slt2 and Rim101 prevents growth in nonosmotically stabilized media (F. Castrejon et al., Eukaryot. Cell 5:507-517, 2006). The double mutant slt2⌬ rim101⌬ displays altered chitin rings, together with a significant reduction in the overall levels of chitin. Cultures of this mutant lyse upon transfer to nonosmotically stabilized media, mostly through the bud, and such lysis is partially prevented by deletion of the chitinase gene (CTS1). Growth of the slt2⌬ rim101⌬ double mutant was restored by the overexpression of the GFA1 or CCT7 genes, which code for two biologically unrelated proteins. Further characterization of the mutant and its suppressors indicated that both Slt2 and Rim101 were independently required for the correct assembly of the septum machinery and that their concomitant absence reduced Chs3 accumulation at the neck, leading to lower levels of chitin. GFA1 overexpression, as well as the addition of glucosamine to the growth medium, specifically suppressed the growth defects by activating chitin synthesis at the neck and restoring the normal assembly of the chitin ring. In contrast, overexpression of CCT7, a Cct chaperonin subunit, alleviated the defect in the septum machinery without affecting chitin synthesis. Both suppressors thus act by reducing neck fragility through different mechanisms and allow growth in nonstabilized media. This work reports new roles for Slt2 and Rim101 in septum formation in budding yeast and confirms the homeostatic role of the chitin ring in the maintenance of neck integrity during cell division.

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Neck compartmentalization as the molecular basis for the different endocytic behaviour of Chs3 during budding or hyperpolarized growth in yeast cells

Sacristán

Reyes

Roncero

2012

Molecular Microbiology

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SummaryYeast cells normally grow by budding, but under certain specific conditions they are also able to grow in hyperpolarized forms reminiscent of hyphal growth. During vegetative growth, the synthesis of the septum that physically separates yeast cells during cytokinesis depends on the correct assembly of the septin ring. Septins and actin patches are assembled at the neck, forming two concentric rings where the actin patch ring occupies the external-most part. This specific positioning defines a plasma membrane region at the neck from which other lateral membrane compartments are excluded. In this scenario, correct assembly of the chitin ring is dependent on the anchoring of Chs3 to the septin ring through Chs4. The anchoring of Chs3 to septins through Chs4 prevents the arrival of this protein at endocytic sites, thus reducing the endocytosis of Chs3. This allows an equilibrium to be set up between the antero-and retrograde transport of Chs3, facilitating the synthesis of the chitin ring at the neck. In contrast, hyperpolarized growth is characterized by a reduced endocytic turnover of Chs3, which in turn lead to the accumulation of Chs3 at the plasma membrane and a concomitant increase in chitin synthesis.

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Abigail Reyes

Chitin synthase III requires Chs4p-dependent translocation of Chs3p into the plasma membrane

Oligomerization of the chitin synthase Chs3 is monitored at the Golgi and affects its endocytic recycling

Slt2 and Rim101 Contribute Independently to the Correct Assembly of the Chitin Ring at the Budding Yeast Neck in Saccharomyces cerevisiae

Neck compartmentalization as the molecular basis for the different endocytic behaviour of Chs3 during budding or hyperpolarized growth in yeast cells

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