Movement of cortical actin patches in yeast.

Waddle, James A.; Karpova, Tatiana S.; Waterston, Robert H.; Cooper, John A.

doi:10.1083/jcb.132.5.861

Cited by 215 publications

(210 citation statements)

References 38 publications

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“…Among them, six showed a partial colocalization with actin bodies (Arc15p, Arc18p, Arc35p, Arp2p, Crn1p, and Srv2p), and five others (Abp1p, Abp140p, Cap1p, Cap2p, and Sac6p) strictly colocalized with actin bodies. Abp1p and Cap1p/ Cap2p are ABPs detected only in actin patches (Drubin et al, 1988;Amatruda and Cooper, 1992;Doyle and Botstein, 1996;Waddle et al, 1996), Abp140p is a protein preferentially found in actin cables (Asakura et al, 1998;Yang and Pon, 2002), and Sac6p has been detected in both actin cables and patches (Drubin et al, 1988;Doyle and Botstein, 1996). To confirm those results and increase when necessary the GFP signal in quiescent cells, 3xGFP fusion proteins were constructed and shown to be functional (see Materials and Methods).…”

Section: Several Actin-binding Proteins Colocalize With Actin Bodiesmentioning

confidence: 77%

“…Within these structures, protein exchange is very dynamic (Yang and Pon, 2002;Kaksonen et al, 2003), and the actin turnover in the filaments that form actin cables and patches is extremely rapid. Indeed, actin patches are very short-lived structures, the half-life of which is estimated to be 20 -40 s (Waddle et al, 1996). Consistently, in living cells, actin filaments rapidly disappear upon treatment with latruculin A (Lat-A), a drug that prevents G-actin polymerization (Ayscough et al, 1997).…”

Section: Actin Bodies Are Stable Structuresmentioning

confidence: 97%

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Actin Bodies in Yeast Quiescent Cells: An Immediately Available Actin Reserve?

Sagot

Pinson

Salin

et al. 2006

MBoC

154

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Most eukaryotic cells spend most of their life in a quiescent state, poised to respond to specific signals to proliferate. In Saccharomyces cerevisiae, entry into and exit from quiescence are dependent only on the availability of nutrients in the environment. The transition from quiescence to proliferation requires not only drastic metabolic changes but also a complete remodeling of various cellular structures. Here, we describe an actin cytoskeleton organization specific of the yeast quiescent state. When cells cease to divide, actin is reorganized into structures that we named "actin bodies." We show that actin bodies contain F-actin and several actin-binding proteins such as fimbrin and capping protein. Furthermore, by contrast to actin patches or cables, actin bodies are mostly immobile, and we could not detect any actin filament turnover. Finally, we show that upon cells refeeding, actin bodies rapidly disappear and actin cables and patches can be assembled in the absence of de novo protein synthesis. This led us to propose that actin bodies are a reserve of actin that can be immediately mobilized for actin cables and patches formation upon reentry into a proliferation cycle.

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Section: Several Actin-binding Proteins Colocalize With Actin Bodiesmentioning

confidence: 77%

Section: Actin Bodies Are Stable Structuresmentioning

confidence: 97%

Actin Bodies in Yeast Quiescent Cells: An Immediately Available Actin Reserve?

Sagot

Pinson

Salin

et al. 2006

MBoC

154

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“…One component of them, the capping protein (Cap2p), was fused to GFP and used as a reporter to monitor patch movement in living cells. Videomicroscopy revealed that changes in patch locations are due to movement of the patches and not to their disassembly and reassembly elsewhere [19].…”

Section: Cytoskeletonmentioning

confidence: 98%

Green fluorescent protein: applications in cell biology

1996

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The green fluorescent protein (GFP) of Aequorea victoria is a unique in vivo reporter for monitoring dynamic processes in cells or organisms. As a fusion tag GFP can be used to localize proteins, to follow their movement or to study the dynamics of the subcellular compartments to which these proteins are targeted. Recent studies where GFP technology has revealed new insights regarding physiological activities of living cells are discussed.

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“…Green fluorescent protein (GFP)-expressing cells were processed as described above with the exception that the spheroplasts were incubated for only 10 min at 37°C. Living spheroplasts were harvested by centrifugation and placed on microscope slide on a pad of 2% (wt/vol) agarose in PBS medium as described previously (Waddle et al, 1996). Cells were imaged using an Olympus AX70 Provis microscope equipped with a CoolSNAP HQ CCD camera controlled by IPlab Spectrum software (Scanalytics, Fairfax, VA).…”

Section: Fluorescence Microscopymentioning

confidence: 99%

“…One intriguing aspect of cortical actin patches is that they are highly motile (Doyle and Botstein, 1996;Waddle et al, 1996). The importance of actin patch motility in vivo is not yet understood, but there is evidence that motility may be initiated by Arp2/3 complex-nucleated actin polymerization (Winter et al, 1997;Kaksonen et al, 2003).…”

Section: Ultrastructure Of Cortical Actin Patches In Yeastmentioning

confidence: 99%

Actin and Septin Ultrastructures at the Budding Yeast Cell Cortex

Rodal

Kozubowski

Goode

et al. 2005

MBoC

174

162

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Budding yeast has been a powerful model organism for studies of the roles of actin in endocytosis and septins in cell division and in signaling. However, the depth of mechanistic understanding that can be obtained from such studies has been severely hindered by a lack of ultrastructural information about how actin and septins are organized at the cell cortex. To address this problem, we developed rapid-freeze and deep-etch techniques to image the yeast cell cortex in spheroplasted cells at high resolution. The cortical actin cytoskeleton assembles into conical or mound-like structures composed of short, cross-linked filaments. The Arp2/3 complex localizes near the apex of these structures, suggesting that actin patch assembly may be initiated from the apex. Mutants in cortical actin patch components with defined defects in endocytosis disrupted different stages of cortical actin patch assembly. Based on these results, we propose a model for actin function during endocytosis. In addition to actin structures, we found that septin-containing filaments assemble into two kinds of higher order structures at the cell cortex: rings and ordered gauzes. These images provide the first high-resolution views of septin organization in cells. INTRODUCTIONBudding yeast has been used for over 20 yr as a model organism to study cytoskeletal function because the genes encoding many components of the cytoskeleton are conserved and because yeast cells are readily amenable to parallel genetic, biochemical, and cell biological analyses. Despite rapid advances in defining the components of the yeast cytoskeleton, its ultrastructure has been difficult to image at the resolution of the electron microscope, with the exception of microtubules (O'Toole et al., 1999). This may be due to the low abundance of the cytoskeleton in yeast relative to mammalian cells, to the presence of a cell wall that complicates extraction procedures, and to high ribosome density in the yeast cytoplasm. As a result, there has been a conspicuous deficit in our understanding of the higher order organization of actin and septin polymers in vivo (Pruyne and Bretscher, 2000). Thus, although it is possible to rapidly identify and mutate cytoskeletal proteins in yeast, there is no method by which to examine the ultrastructural consequences of these mutations. This gap could be filled by developing an approach to image the yeast cytoskeleton at high resolution.The yeast actin cytoskeleton is organized into three distinct structures: motile cortical patches that are polarized in the growing bud, actin cables that run along the motherdaughter cell axis, and a contractile cytokinetic ring at the neck of dividing cells (reviewed in Pruyne and Bretscher, 2000). Cortical actin patches contain many of the actin-associated proteins common to all eukaryotes (Goode and Rodal, 2001) and are composed of actin filaments that undergo rapid turnover (Ayscough et al., 1997). Actin is essential for yeast endocytosis (Kubler and Riezman, 1993). A number of recent studies suggest that act...

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Movement of cortical actin patches in yeast.

Cited by 215 publications

References 38 publications

Actin Bodies in Yeast Quiescent Cells: An Immediately Available Actin Reserve?

Actin Bodies in Yeast Quiescent Cells: An Immediately Available Actin Reserve?

Green fluorescent protein: applications in cell biology

Actin and Septin Ultrastructures at the Budding Yeast Cell Cortex

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