Muqing Cao scite author profile

The role of the primary cilium in key signaling pathways depends on dynamic regulation of ciliary membrane protein composition, yet we know little about the motors or membrane events that regulate ciliary membrane protein trafficking in existing organelles. Recently, we showed that cilium-generated signaling in Chlamydomonas induced rapid, anterograde IFT-independent, cytoplasmic microtubule-dependent redistribution of the membrane polypeptide, SAG1-C65, from the plasma membrane to the periciliary region and the ciliary membrane. Here, we report that the retrograde IFT motor, cytoplasmic dynein 1b, is required in the cytoplasm for this rapid redistribution. Furthermore, signaling-induced trafficking of SAG1-C65 into cilia is unidirectional and the entire complement of cellular SAG1-C65 is shed during signaling and can be recovered in the form of ciliary ectosomes that retain signal-inducing activity. Thus, during signaling, cells regulate ciliary membrane protein composition through cytoplasmic action of the retrograde IFT motor and shedding of ciliary ectosomes.DOI: http://dx.doi.org/10.7554/eLife.05242.001

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Flagellar regeneration requires cytoplasmic microtubule depolymerization and kinesin-13

Wang

Piao

Cao

et al. 2013

102

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SummaryIn ciliated cells, two types of microtubules can be categorized: cytoplasmic and axonemal. It has been shown that axonemal tubulins come from a 'cytoplasmic pool' during cilia regeneration. However, the identity and regulation of this 'pool' is not understood. Previously, we have shown that Chlamydomonas kinesin-13 (CrKin13) is phosphorylated during flagellar regeneration, and required for proper flagellar assembly. In the present study, we show that CrKin13 regulates depolymerization of cytoplasmic microtubules to control flagellar regeneration. After flagellar loss and before flagellar regeneration, cytoplasmic microtubules were quickly depolymerized, which was evidenced by the appearance of sparse and shorter microtubule arrays and increased free tubulins in the cell body. Knockdown of CrKin13 expression by RNA interference inhibited depolymerization of cytoplasmic microtubules and impaired flagellar regeneration. In vitro assay showed that CrKin13 possessed microtubule depolymerization activity. CrKin13 underwent phosphorylation during microtubule depolymerization, and phosphorylation induced targeting of CrKin13 to microtubules. The phosphorylation of CrKin13 occurred at residues S100, T469 and S522 as determined by mass spectrometry. Abrogation of CrKin13 phosphorylation at S100 but not at other residues by inducing point mutation prevented CrKin13 targeting to microtubules. We propose that CrKin13 depolymerizes cytoplasmic microtubules to provide tubulin precursors for flagellar regeneration.

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Chlamydomonas (Chlorophyceae) colony PCR

Cao

Guo

et al. 2009

Protoplasma

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The ease and effectiveness of colony polymerase chain reaction (PCR) has allowed rapid amplification of DNA fragments and screening of large number of colonies of interest including transformants and mutants with genetic manipulations. Here, we evaluated colony PCR in Chlamydomonas. Individual colonies were treated with 10 mM ethylenediaminetetraacetic acid (EDTA) or Chelex-100 and the resulting clear cell lysate was used for PCR reaction. Either genomic DNA or plasmid DNA incorporated into the genome was equally amplified. We found that the Chelex method is superior to EDTA method in certain cases. This colony PCR technique will bypass the tedious process of isolating genomic DNA for PCR reaction and will make it possible for rapid amplification of genomic DNA fragments as well as rapid large-scale screening of transformants.

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The Phosphorylation State of an Aurora-Like Kinase Marks the Length of Growing Flagella in Chlamydomonas

et al. 2011

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Flagella and cilia are structurally polarized organelles whose lengths are precisely defined, and alterations in length are related to several human disorders [1, 2]. Intraflagellar transport (IFT) and protein signaling molecules are implicated in specifying flagellar/ciliary length [3–6], but evidence has been lacking for a flagellum/cilium length sensor that could participate in active length control or establishment of structural polarity. Previously, we showed that the phosphorylation state of the aurora-like protein kinase CALK in Chlamydomonas is a marker of the absence of flagella. Here, we show that CALK phosphorylation state also is a marker for flagellar length. CALK is phosphorylated in cells without flagella, and during flagellar assembly it becomes desphosphorylated. Dephosphorylation is not simply a consequence of initiation of flagellar assembly or of time after experimentally-induced flagellar loss, but requires flagellar assembly to a threshold length. Analysis of cells with flagella of varying lengths shows that the threshold length for CALK dephosphorylation is ~6 µm (half-length). Studies with short and long flagellar mutants indicate that cells detect absolute rather than relative flagellar length. Our results demonstrate that cells possess a mechanism for translating flagellar length into a posttranslational modification of a known flagellar regulatory protein.

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Activation loop phosphorylation of a protein kinase is a molecular marker of organelle size that dynamically reports flagellar length

Cao

Meng

Wang

et al. 2013

Proc. Natl. Acad. Sci. U.S.A.

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Specification of organelle size is crucial for cell function, yet we know little about the molecular mechanisms that report and regulate organelle growth and steady-state dimensions. The biflagellated green alga Chlamydomonas requires continuouslength feedback to integrate the multiple events that support flagellar assembly and disassembly and at the same time maintain the sensory and motility functions of the organelle. Although several length mutants have been characterized, the requisite molecular reporter of length has not been identified. Previously, we showed that depletion of Chlamydomonas aurora-like protein kinase CALK inhibited flagellar disassembly and that a gel-shiftassociated phosphorylation of CALK marked half-length flagella during flagellar assembly. Here, we show that phosphorylation of CALK on T193, a consensus phosphorylation site on the activation loop required for kinase activity, is distinct from the gel-shift-associated phosphorylation and is triggered when flagellar shortening is induced, thereby implicating CALK protein kinase activity in the shortening arm of length control. Moreover, CALK phosphorylation on T193 is dynamically related to flagellar length. It is reduced in cells with short flagella, elevated in the long flagella mutant, lf4, and dynamically tracks length during both flagellar assembly and flagellar disassembly in WT, but not in lf4. Thus, phosphorylation of CALK in its activation loop is implicated in the disassembly arm of a length feedback mechanism and is a continuous and dynamic molecular marker of flagellar length during both assembly and disassembly.cilia and flagella | flagellar length control | cilia length | organelle size control | aurora kinase U nderstanding control of organelle size is a fundamental problem in cell biology. Eukaryotic flagella and cilia have been used as simple systems to address this question because their size can be simply defined as length and can be easily tracked and measured (1). After flagellar amputation in Chlamydomonas, rapid flagellar elongation occurs followed by a decreased elongation rate as the organelles approach their full length (∼12 μm) (2). Flagellar precursors delivered by intraflagellar transport (IFT) to the flagellar tip drive assembly of the microtubule-rich axoneme (3, 4). Steady-state length is established when the rate of assembly comes into balance with the basal rate of disassembly (5-7).The relatively constant amount of IFT complexes within flagella that supports elongation is controlled in the cytoplasm (5, 6). The frequency of injection of groups of IFT complexes (trains) into the flagellum increases with increasing length, whereas IFT train size shows a corresponding decrease with increasing length (7). In addition, the rate of transcription of flagellar genes and transcript stability change during elongation (reviewed in ref. 8). When flagellar shortening is triggered, the number of IFT complexes entering increases two-to fourfold, but the complexes carry much less anterograde cargo (9). In addition, a d...

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Muqing Cao

Uni-directional ciliary membrane protein trafficking by a cytoplasmic retrograde IFT motor and ciliary ectosome shedding

Flagellar regeneration requires cytoplasmic microtubule depolymerization and kinesin-13

Chlamydomonas (Chlorophyceae) colony PCR

The Phosphorylation State of an Aurora-Like Kinase Marks the Length of Growing Flagella in Chlamydomonas

Activation loop phosphorylation of a protein kinase is a molecular marker of organelle size that dynamically reports flagellar length

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