Distinct acto/myosin-I structures associate with endocytic profiles at the plasma membrane

doi:10.1083/jcb.200708060

Published online
doi:10.1083/jcb.200708060
The Journal of Cell Biology, Vol. 180, No. 6, 1219-1232
The Rockefeller University Press, 0021-9525 $30.00
© Idrissi et al.

This Article

	Abstract
	Full Text (PDF, 4106K)
	PPT slides of all figures
	Supplemental Material Index
	Alert me when this article is cited
	Citation Map

Services

	Email this article
	Similar articles in this journal
	Similar articles in PubMed
	Alert me to new content in the JCB
	Download to citation manager

Citing Articles

	Citing Articles via HighWire
	Citing Articles via CrossRef
	Citing Articles via Google Scholar

Google Scholar

	Articles by Idrissi, F.-Z.
	Articles by Geli, M.-I.
	Search for Related Content

PubMed

	PubMed Citation
	Articles by Idrissi, F.-Z.
	Articles by Geli, M.-I.


Related Collections

	Related Article

Social Bookmarking

	What's this?

Article

Distinct acto/myosin-I structures associate with endocytic profiles at the plasma membrane

Fatima-Zahra Idrissi¹, Helga Grötsch¹, Isabel M. Fernández-Golbano¹, Cristina Presciatto-Baschong², Howard Riezman³, and María-Isabel Geli¹

¹ Instituto de Biología Molecular de Barcelona, Consejo Superior de Investigaciones Científicas, 08028 Barcelona, Spain
² Biozentrum, University of Basel, CH-4056 Basel, Switzerland
³ University of Geneva, CH-1211 Geneva, Switzerland

Correspondence to María-Isabel Geli: mgfbmc{at}ibmb.csic.es

Endocytosis in yeast requires actin and clathrin. Live cellimaging has previously shown that massive actin polymerizationoccurs concomitant with a slow 200-nm inward movement of theendocytic coat (Kaksonen, M., Y. Sun, and D.G. Drubin. 2003.Cell. 115:475–487). However, the nature of the primaryendocytic profile in yeast and how clathrin and actin cooperateto generate an endocytic vesicle is unknown. In this study,we analyze the distribution of nine different proteins involvedin endocytic uptake along plasma membrane invaginations usingimmunoelectron microscopy. We find that the primary endocyticprofiles are tubular invaginations of up to 50 nm in diameterand 180 nm in length, which accumulate the endocytic coat componentsat the tip. Interestingly, significant actin labeling is onlyobserved on invaginations longer than 50 nm, suggesting thatinitial membrane bending occurs before initiation of the slowinward movement. We also find that in the longest profiles,actin and the myosin-I Myo5p form two distinct structures thatmight be implicated in vesicle fission.

Abbreviations used in this paper: GDIT, gold distance to invaginationtip; GDLB, gold distance to lipid bilayer; GDPM, gold distanceto plasma membrane; GRP, gold relative position; IL, invaginationlength; WASP, Wiskott-Aldrich syndrome protein.

Introduction

Top
Abstract
Introduction
Results
Discussion
Materials and methods
References

Genetic analysis of the endocytic uptake in yeast identified>50 proteins involved in the process, including clathrin,actin, and numerous proteins that control actin dynamics (Engqvist-Goldstein and Drubin, 2003).Whether clathrin and actin cooperated within the same pathwayin yeast and the sequence of events driving formation of theprimary endocytic vesicles remained completely open questionsuntil recent development of live cell fluorescence microscopyapplied to this organism (Kaksonen et al., 2003). This techniqueshowed that once a cortical site is marked by the clathrin coat,recruitment of all other endocytic proteins, including thosecontrolling actin dynamics, follows in a highly reproducible,ordered, and linear manner (Kaksonen et al., 2003, 2005; Jonsdottir and Li, 2004;Newpher et al., 2005; Toshima et al., 2006; Sun et al., 2006,2007). Based on differences in protein function and dynamicsat the endocytic cortical patch, four molecular modules havebeen defined (Kaksonen et al., 2005): (1) the endocytic coatmodule composed of clathrin (Chc1p/Clc1p) and several clathrin-interactingproteins such as the Hip1R homologue Sla2p, the intersectin-likeproteins Sla1p and End3p, and the eps15 family member Pan1p;(2) the Wiskott-Aldrich syndrome protein (WASP)/Myo module containingthe yeast WASP (Las17p) and WASP-interacting protein (Vrp1p)homologues, the unconventional myosin-I Myo5p, the Myo5p-interactingprotein Bbc1p, and the yeast syndapin Bzz1p; (3) the vesiclefission module containing the yeast amphiphysins Rvs161p andRvs167p; and (4) the actin module, which includes the Arp2/3pcomplex, the actin binding protein Abp1p, capping protein (Cap1/2p),and fimbrin (Sac6p).

The coat components and Las17p are the first to be observedas patches at the plasma membrane (Kaksonen et al., 2003, 2005;Newpher et al., 2005; Toshima et al., 2006). After a periodof restrained motility, which can last >1 min, the coat undergoesa 200-nm slow inward movement, which takes $~$ 10–15 s. Shortlyafter the transient recruitment of the yeast amphiphysins, thecoat starts disassembling as it rapidly moves into the cytosol(Kaksonen et al., 2003, 2005). The released vesicle then movesrapidly into the cell along actin cables to finally fuse withinternal compartments (Kaksonen et al., 2003; Huckaba et al., 2004;Toshima et al., 2006). The unconventional myosin-I Myo5p isrecruited at the endocytic patch at the onset of the slow inwardmovement together with Bbc1p and slightly after Bzz1p and Vrp1p.All components of the WASP/Myo module stay at the plasma membraneas the vesicle detaches, and they are thought to orchestrateArp2/3-dependent actin polymerization at sites of endocytosis(Sun et al., 2006). Finally, coincident with initiation of theslow inward movement and with the onset of massive actin polymerizationis also the recruitment of the actin module, which remains associatedwith the endocytic vesicle as it moves into the cytosol (Kaksonen et al., 2003,2005). Based on the time of recruitment of the yeast amphiphysins,it has been proposed that the slow inward movement representsthe initial invagination of the plasma membrane (Kaksonen et al., 2006).However, the precise point when vesicle fission occurs has notbeen determined. Furthermore, it is not really understood howclathrin and actin machineries cooperate to drive membrane invaginationand vesicle fission.

Fluorescence microscopy does not offer sufficient resolutionto define the nature of the primary endocytic profiles and todissect the architecture of the molecular complexes during initialmembrane bending. In contrast to mammalian cells, the ultrastructuralstudies on the early stages of endocytic budding in yeast havebeen scarce and difficult to interpret (Mulholland et al., 1994,1999). In this study, we use immunoelectron microscopy to analyzeplasma membrane–associated profiles decorated for componentsof the different endocytic modules. With the live cell imagingdata in hand, the ultrastructural analysis indicates that theprimary endocytic profiles in yeast are tubular invaginationsof up to 50 nm in diameter and 180 nm in length. Analysis ofthe distribution of immunogold labeling nine different proteinsrequired for the endocytic uptake shows that they segregatealong endocytic invaginations. The data provide essential informationto model the molecular mechanism driving endocytic uptake inyeast and unveil interesting similarities and differences withthe analogous process in mammals.

Results

Top
Abstract
Introduction
Results
Discussion
Materials and methods
References

Yeast proteins involved in endocytic uptake label tubular invaginations of up to 50 nm in diameter and 180 nm in length
The actual point when vesicle scission from the plasma membraneoccurs during the 200-nm coat slow inward movement has not beendefined. Small vesicles could form at the plasma membrane thatthen slowly move through a dense cortex. Alternatively, theendocytic coat could progress into the cytosol at the tip oftubular profiles while still attached to the plasma membrane.To define the nature of the primary endocytic profiles in yeast,we used immunoelectron microscopy to analyze the morphologyof membrane profiles located within 200 nm from the cell surface(plasma membrane invaginations and vesicles), which could beimmunolabeled with gold particles directed against the endocyticcoat components. Because the coat proteins are recruited firstto the sites of endocytosis and only disassemble once the fastinward movement starts, we reasoned that labeling against thesecomponents should decorate the incipient endocytic profilesat all maturation stages. Ultrathin sections from chemicallyfixed yeast cells expressing HA-tagged versions of Sla1p orPan1p were prepared and labeled using a rat monoclonal antibodyagainst HA or a mixture of monoclonal antibodies against clathrin(Chc1p) and the adequate colloidal gold-conjugated secondaryantibodies. Micrographs of membrane profiles decorated withgold against the coat were collected, and their length (invaginationlength [IL]) and diameter were measured. This type of analysisdemonstrated that all components of the endocytic coat associatewith tubular invaginations with diameters varying between 35and 50 nm and lengths up to 180 nm, which were often surroundedby an electron-dense material (Fig. 1 and Table S1, availableat http://www.jcb.org/cgi/content/full/jcb.200708060/DC1). Interestingly, no significant labeling associated with smallvesicles close to the plasma membrane was observed. These observationswere consistent with the hypothesis proposing that the endocyticcoat progresses inside the cell in association with tubularprofiles before vesicle scission.

View larger version (49K):
[in this window]
[in a new window]
[Download PPT slide]

Figure 1. Proteins involved in the endocytic uptake associate with plasma membrane invaginations of about 50 nm in diameter and up to 180 nm in length. Representative electron micrographs of ultrathin sections from yeast showing plasma membrane–associated invaginations shorter than 50 nm, between 50 nm and 100 nm, and longer than 100 nm decorated with gold particles against the indicated proteins. Sections of yeast strains expressing HA-tagged Sla1p (HR2634/pMIG692), Pan1p (ScMIG946), Rvs167p (ScMIG995), Abp1p (ScMIG723), Myo5p (ScMIG994), Bbc1p (ScMIG903), and Las17p (ScMIG516) were decorated with a rat monoclonal anti-HA antibody and the appropriate 10-nm gold-conjugated secondary IgGs. Chc1p and actin (Act1p) were localized on ultrathin sections of ScMIG946 using a mixture of mouse monoclonal anti-Chc1p antibodies or a mouse monoclonal anti-actin antibody, respectively, and the appropriate 20-nm gold-conjugated secondary IgGs. Bar, 100 nm.

To investigate whether the plasma membrane–associatedtubular profiles were actually endocytic invaginations thatgrow into the cytosol during the slow inward movement, we examinedthe presence of Abp1p and Rvs167p on similar invaginations.Abp1p is recruited to the cell cortex at the beginning of theslow inward movement, whereas the yeast amphiphysins are thelast proteins arriving before initiation of the fast inwardmovement (Kaksonen et al., 2005). Micrographs from yeast cellsexpressing HA-tagged versions of these proteins were preparedand analyzed as described in the previous paragraph. Consistentwith our hypothesis, gold decorating Abp1p and Rvs167p againappeared near tubular profiles similar to those labeled forSla1p, Pan1p, and Chc1p (Fig. 1). Interestingly, however, andin contrast to gold decorating the coat, no significant labelingfor Abp1p and Rvs167p was detected in association with profilesshorter than 50 nm (Fig. 2). Only one gold particle out of120 decorating Rvs167p and none decorating Abp1p appeared tobe associated with short profiles, whereas >20% of the goldlabeling the endocytic coat were found near this kind of profile(IL $≤$ 50 nm; Fig. 2). These data suggested that initial membranebending might occur before assembly of the actin module, previousto initiation of the slow inward movement and massive actinpolymerization. Consistently, only 5% of the particles labelingactin (Act1p) were associated with invaginations shorter than50 nm (Fig. 2). Also in striking agreement with this hypothesiswas the distribution of gold particles decorating differentproteins of the WASP/Myo module. Again, 19% of the labelingagainst Las17p, which is recruited to the endocytic patch beforeinitiation of the slow inward movement, was found on invaginationsshorter than 50 nm. In contrast, <5% of the gold particlesdecorating Bbc1p and Myo5p, which arrive at the cortical patchat the onset of the slow inward movement, were found associatedwith this type of profile. Consistent with the relatively similardynamics of the coat components and Las17p at the endocyticpatch, protein comparison for the length of the labeled invaginations(IL) using a generalized linear model demonstrated that Las17pwas more similar to Pan1p than to the members of the WASP/Myomodule (Table I).

View larger version (43K):
[in this window]
[in a new window]
[Download PPT slide]

Figure 2. Shallow plasma membrane invaginations are almost devoid of endocytic proteins recruited during the slow inward movement. Frequency of gold decorating the indicated proteins binned according to the length of the associated invagination (IL; 50-nm bins). Gold-labeled ultrathin sections were prepared as described in Fig. 1, and the length of the associated plasma membrane invagination was measured. The number of gold particles associated with invaginations of lengths within the indicated ranges were counted and normalized against the total number of gold particles recorded for each protein (n_g). The total number of invaginations (n_i) associated with the recorded gold particles is indicated.

View this table:
[in this window]
[in a new window]

Table I. Protein comparison for the IL parameter using a generalized linear model

The observation that gold frequencies labeling the differentproteins binned for the length of the associated invaginationapproximately recapitulated their dynamics at the endocyticpatch (Fig. 2) strongly indicated that tubular invaginationsof increasing length represent progressively more mature endocyticprofiles.

Proteins required for endocytic uptake spatially segregate along plasma membrane invaginations
In light of the live cell fluorescence microscopy data (Kaksonen et al., 2005),our results strongly indicated that endocytic budding in yeastrequires the formation of tubular invaginations that grow intothe cytosol before vesicle scission. To obtain information regardingthe architecture of endocytic complexes along these membraneprofiles, we analyzed the distribution of gold particles labelingcomponents of different endocytic modules. Several parameterswere measured for every recorded immunogold. In addition tothe length of the labeled invagination (IL), the distance fromthe gold particle to the basal plasma membrane (gold distanceto plasma membrane [GDPM]), the distance from the gold particleto the invagination tip (gold distance to invagination tip [GDIT]= GDPM – IL), and the relative position of the gold particlewith respect to the invagination (gold relative position [GRP]= GDPM/IL) were analyzed (Fig. 3 A). GRPs close to 1 describedgold localized at the invagination tip, and GRPs near 0 definedgold particles situated at the base of the invagination (plasmamembrane), close to the negatively curved area. GRPs >1 describedgold particles located at the distal area. In addition, theminimal distance of the gold particle to the lipid bilayer (golddistance to lipid bilayer [GDLB]) was measured (Fig. 3 A). Togain information about possible rearrangements in the architectureof endocytic complexes as invaginations elongate, the GDPM,GDIT, and GRP parameters were plotted against the IL (Fig. 3 B).The distribution of these parameters was then analyzed for theentire immunogold population labeling each protein and for thesubpopulations associated with short (IL $≤$ 50 nm), intermediate(50 nm < IL $≤$ 100 nm), and long (IL > 100 nm) invaginations(Fig. 3; and see Figs. 4, 5, and 6).

View larger version (51K):
[in this window]
[in a new window]
[Download PPT slide]

Figure 3. Endocytic coat components accumulate at the tip of tubular invaginations. (A) Scheme of an immunogold-labeled invagination showing the parameters used to characterize the particle position: invagination length (IL), gold distance to the basal plasma membrane (GDPM), gold distance to the invagination tip (GDIT = GDPM – IL), gold relative position (GRP = GDPM/IL), and minimal gold distance to the lipid bilayer (GDLB). (B) Graphs representing the GDPM for each recorded gold particle immunolabeling Sla1p, Pan1p, and Chc1p versus the IL. The x axis represents the level of the basal plasma membrane. The red dotted lines indicate the positions of the invagination tip. Gray lines converging at the xy axes crossing point define the GRP areas (left axis) as a function of the IL. Gray, red, and green areas enclose the gold subpopulations associated with short (IL $≤$ 50 nm), intermediate (50 nm < IL $≤$ 100 nm), and long (IL > 100 nm) profiles, respectively. Sample sizes of subpopulations associated with short, intermediate, and long profiles are indicated as n_s, n_m, and n_l, respectively. (C) Graphs representing the frequency of gold labeling Sla1p, Pan1p, and Chc1p binned according to their GRP, GDIT, or GDPM. The entire gold subpopulation (total; black) and the subpopulations associated with short ( $≤$ 50; gray), intermediate (50–100; red) and long (>100; green) profiles were analyzed. The number of gold particles with values falling into the indicated intervals was counted and normalized with respect to the total population (n_g; Fig. 2) or for the corresponding subtotals (n_s, n_m, and n_l). Immunogold-labeled ultrathin sections were prepared as described in Fig. 1. (A and C) Black and red dotted lines indicate the positions of the basal plasma membrane (PM) and the invagination tip (IT), respectively.

Analysis of gold labeling the coat components Sla1p, Pan1p,and Chc1p indicated that they were all tightly associated withthe invagination tip (Figs. 1 and 3 B). Particles labeling theseproteins exhibited mean GRP values near 1, with >80% of theparticles located <40 nm from the invagination tip (Fig. 3 Cand Table S2, available at http://www.jcb.org/cgi/content/full/jcb.200708060/DC1).The observation that the mean GDIT did not significantly changewith the IL, whereas the mean GDPM clearly increased (Fig. 3, B and C;Table II; and Table S2), suggested that the coat travels intothe cytosol at the tip of the tubular profiles. Consistentwith the similar dynamics of Sla1p, Pan1p, and Chc1p at theendocytic patch (Kaksonen et al., 2005), statistical comparisonof the coat components failed to demonstrate significant differences(P < 0.02) for any of the positional parameters (GRP, GDIT,GDPM, and GDLB) analyzed (Table III). All of these resultsstrongly suggested that the endocytic coat forms a complex thatmoves into the cytosol at the tip of tubular profiles.

View this table:
[in this window]
[in a new window]

Table II. Homogeneity analysis for the GRP, GDIT, GDPM, and GDLB parameters using the Kruskal-Wallis test

View this table:
[in this window]
[in a new window]

Table III. Protein comparison for the GRP, GDIT, GDPM, and GDLB parameters using a generalized linear model

The apical distribution observed for Sla1p, Pan1p, and Chc1pseemed to be specific for the coat components. Gold labelingRvs167p preferred a slightly negatively curved area situatedimmediately beneath the region where particles labeling thecoat accumulated (Fig. 1 and Fig. 4 A). Statistical comparisonof Rvs167p with the coat components demonstrated very significantdifferences for all positional parameters analyzed except forGDLB (Table III). Rvs167p labeling was found concentrated withina subapical area, with a mean GRP near 0.6 (Figs. 1 and 4 B;and Table S2). The mean GDIT for Rvs167p was close to –40nm (Fig. 4 B and Table S2). Again, it did not significantlychange as a function of IL, whereas the mean GDPM did, suggestingthat the yeast amphiphysin follows the endocytic coat as itmoves into the cytosol (Fig. 4 and Tables II and S2).

View larger version (23K):
[in this window]
[in a new window]
[Download PPT slide]

Figure 4. The yeast amphiphysin Rvs167p occupies a subapical area on plasma membrane–associated invaginations. (A) Graph representing the GDPM for each recorded gold particle labeling Rvs167p versus the IL. The x axis represents the level of the basal plasma membrane. The red dotted line indicates the position of the invagination tip. Gray lines converging at the xy axes crossing point define the GRP areas (left axis) as a function of the IL. Gray, red, and green areas enclose the gold subpopulations associated with short (IL $≤$ 50 nm), intermediate (50 nm < IL $≤$ 100 nm), and long (IL > 100 nm) profiles, respectively. Sample sizes of subpopulations associated with short, intermediate, and long profiles are indicated as n_s, n_m, and n_l, respectively. (B) Graphs representing the frequency of gold labeling Rvs167p binned according to their GRP, GDIT, or GDPM. The entire gold subpopulation (total; black) and the subpopulations associated with intermediate (50–100; red) and long (>100; green) profiles were analyzed. The number of gold particles with values falling into the indicated intervals was counted and normalized with respect to the total population (n_g; Fig. 2) or for the corresponding subtotals (n_m and n_l). Dotted black and red lines indicate the positions of the basal plasma membrane and the invagination tip, respectively. Immunogold-labeled ultrathin sections were prepared as described in Fig. 1.

Analysis of the distribution of gold decorating Abp1p and actinindicated that these proteins form a loose cloud around thetip that spreads toward the base (Fig. 1 and Fig. 5). Theactin and Abp1p distribution was consistent with that previouslydescribed using rapid-freeze and deep-etch electron microscopytechniques (Rodal et al., 2005). Statistical comparison of Abp1por actin with the coat components did not show significant differencesregarding the GRP, GDIT, and GDPM parameters (Table III). Similarto the coat, Abp1p and actin had GRP mean values near 1 eventhough the particles decorating these proteins seemed to spreadmore along the entire invagination (Fig. 5 and Table S2). However,in contrast to Rvs167p, Abp1p and actin exhibited very significantdifferences with the coat components when the GDLB parameterwas used for comparison (Table III). On average, particles decoratingSla1p, Pan1p, Chc1p, and Rvs167p were found at $~$ 10 nm from thelipid bilayer, whereas those decorating Act1p and Abp1p werelocated at $~$ 20 nm from the membrane (Table S2).

View larger version (45K):
[in this window]
[in a new window]
[Download PPT slide]

Figure 5. Actin segregates into two distinct pools in long plasma membrane invaginations. (A) Graphs representing the GDPM for each recorded gold particle labeling Abp1p or actin (Act1p) versus the IL. The x axis represents the level of the basal plasma membrane. The red dotted lines indicate the positions of the invagination tip. Gray lines converging at the xy axes crossing point define the GRP areas (left axis) as a function of the IL. Gray, red, and green areas enclose the gold subpopulations associated with short (IL $≤$ 50 nm), intermediate (50 nm < IL $≤$ 100 nm), and long (IL > 100 nm) profiles, respectively. Sample sizes of subpopulations associated with short, intermediate, and long profiles are indicated as n_s, n_m, and n_l, respectively. (B) Graphs representing the frequency of gold labeling Abp1p or Act1p binned according to their GRP, GDIT, or GDPM. The entire gold subpopulation (total; black) and the subpopulations associated with intermediate (50–100; red) and long (>100; green) profiles were analyzed. The number of gold particles with values falling into the indicated intervals was counted and normalized with respect to the total population (n_g; Fig. 2) or for the corresponding subtotals (n_m and n_l). Dotted black and red lines indicate the positions of the basal plasma membrane and the invagination tip, respectively. Immunogold-labeled ultrathin sections were prepared as described in Fig. 1.

Closer inspection of the distribution of particles labelingactin and Abp1p demonstrated some other important differenceswith the coat (Figs. 3 and Figs.5). In contrast to Sla1p, Pan1p,and Chc1p, the Kruskal-Wallis test showed significant divergencesbetween the subpopulations of particles labeling Abp1p on intermediate(50 nm $≤$ IL < 100 nm) and long (IL $≥$ 100 nm) profiles for GRPand GDIT but not for GDPM (Table II). Analysis of the gold frequencybinned for GDIT on intermediate and long profiles indicatedthat in contrast to the coat components, Abp1p spreads towardthe profile base as the invagination elongates (Fig. 5 B). Interestingly,particles labeling actin did not exhibit the same pattern asAbp1p in the longest profiles (Fig. 5). Analysis of the goldfrequency binned for GRP, GDIT, and GDPM indicated that in longprofiles, actin split into two different pools associated withthe base and the tip of the invagination (Figs. 1 and 5 B).The two gold subpopulations were most evident when profileslonger than 110 nm were analyzed (Fig. S1, available at http://www.jcb.org/cgi/content/full/jcb.200708060/DC1).In the very long invaginations, $~$ 35% and 45% of the particleslabeling actin were found associated with the invagination base(GRP = –0.2–0.3) and tip (GRP = 0.8–1.3),respectively, whereas <5% was found at the intermediate region(GRP = 0.3–0.8); Fig. S1 A). The ${chi}$ ² test applied to thegold frequencies in those GRP regions for three independentgold countings demonstrated that the likelihood ratio was verysmall (P = 0.013; Fig. S1 B).

Finally, we investigated the distribution of gold decoratingthe most potent actin-nucleating promoting factors during endocyticuptake: Myo5p and Las17p (Sun et al., 2006). In addition, weanalyzed the distribution of Bbc1p, a protein that has beenshown to act as an inhibitor of both Las17p and Myo5p (Sun et al., 2006).Myo5p, Las17p, and Bbc1p remain at the plasma membrane as thecoat and the actin modules move into the cytosol. Thus, we expectedto see important differences in their distribution when comparedwith other endocytic modules.

Accordingly, we found that Myo5p labeling exhibited an exclusivepattern, with most particles located near the basal plasma membrane(Fig. 6). More than 65% of the gold had GDPM values inferiorto 40 nm (Fig. 6 B and Table S2). Gold particles decoratingMyo5p were often tightly associated with the negatively curvedarea (Fig. 1). Statistical comparison of the entire populationof gold labeling Myo5p with those decorating the coat, actin,or fission modules showed very significant differences for GRP,GDIT, and GDPM (Table III). Interestingly, however, closer inspectionof the Myo5p gold distribution in the longest profiles indicatedthat similar to actin, the myosin-I segregated into two distinctpools: one of them was still associated with the invaginationbase, and the other was associated with the tip (Figs. 1 and6 B). In profiles longer than 110 nm, $~$ 55% and 35% of the particleslabeling Myo5p were found at the invagination base (GRP = –0.2–0.3)or at the tip (GRP = 0.8–1.3), respectively, whereas <10%was close to the intermediate region (GRP = 0.3–0.8; Fig.S1 A). A ${chi}$ ² test applied to the gold frequencies in those GRPregions for three independent gold countings demonstrated thatthe likelihood ratio was very small (P $≤$ 0.001; Fig. S1 B).

View larger version (65K):
[in this window]
[in a new window]
[Download PPT slide]

Figure 6. Myo5p but not Las17p or Bbc1p mimics the distribution of actin in long profiles. (A) Graphs representing the GDPM for each recorded gold particle labeling Myo5p, Bbc1p, or Las17p versus the IL. The x axis represents the level of the basal plasma membrane. The red dotted lines indicate the positions of the invagination tip. Gray lines converging at the xy axes crossing point define the GRP areas (left axis) as a function of the IL. Gray, red, and green areas enclose the gold subpopulations associated with short (IL $≤$ 50 nm), intermediate (50 nm < IL $≤$ 100 nm), and long (IL > 100 nm) profiles, respectively. Sample sizes of subpopulations associated with short, intermediate, and long profiles are indicated as n_s, n_m, and n_l, respectively. (B) Graphs representing the frequency of gold labeling Myo5p, Bbc1p, or Las17p binned according to their GRP, GDIT, or GDPM. The entire gold subpopulation (total; black) and the subpopulations associated with intermediate (50–100; red) and long (>100; green) profiles were analyzed for Myo5p, Bbc1p, and Las17p. In addition, the distribution for the Las17p subpopulation associated with short profiles ( $≤$ 50 nm; gray) was included. The number of gold particles with values falling into the indicated intervals was counted and normalized with respect to the total population (n_g; Fig. 2) or for the corresponding subtotals (n_s, n_m, and n_l). Dotted black and red lines indicate the positions of the basal plasma membrane and the invagination tip, respectively. Immunogold-labeled ultrathin sections were prepared as described in Fig. 1.

Surprisingly, although Bbc1p and Las17p physically and functionallyinteract with Myo5p (Anderson et al., 1998; Geli et al., 2000;Lechler et al., 2000; Drees et al., 2001; Mochida et al., 2002),and Bbc1p and Myo5p have identical dynamics at the corticalpatch (Sun et al., 2006), the distribution of gold labelingBbc1p and Las17p was significantly different from those decoratingMyo5p, specially when GRP and GDPM parameters were considered(P < 0.001; Fig. 6 and Table III). Similar to Rvs167p (Fig. 4),gold against Bbc1p and Las17p mostly occupied the invaginationintermediate area, with GRP values near 0.6 regardless of theIL (Fig. 6 B, Table II, and Table S2). Consistently, proteincomparison using a generalized linear model could not demonstratesignificant differences between Bbc1p, Las17p, and Rvs167p forany of the positional parameters analyzed except for GDLB (particlesdecorating Bbc1p appeared slightly more separated from the lipidbilayer; Table III and Table S2). In contrast, statistical analysisdemonstrated very significant differences (P < 0.008) withMyo5p for GRP, GDIT, and GDPM (Figs. 4 and 6, Table III, andTable S2).

Two distinct acto/myosin-I pools associate with deeply invaginated endocytic profiles
Our data strongly indicated that proteins involved in the endocyticuptake segregate along plasma membrane invaginations. One ofour most striking observations, which could not be predictedfrom previous experiments, was that actin and Myo5p rearrangein the longest profiles to generate two acto/myosin-I structuresassociated with the base and tip of the endocytic invaginations.

Differences and similarities between the patterns of particleslabeling Myo5p and actin as a function of IL were most obviouswhen subpopulations associated with profiles shorter than 80nm or longer than 110 nm were compared (Fig. S1 and Table IV). The Kruskal-Wallis test failed to evidence statistically significantdifferences between the actin and Myo5p gold subpopulationsassociated with profiles longer than 110 nm for any positionalparameters, whereas highly significant differences (P < 0.0004)could be demonstrated for all parameters in shorter profilesusing similar sample sizes (Table IV). These data demonstratedthat although in short profiles, the distributions of gold decoratingactin and Myo5p were complementary, in the longest profiles,actin and myosin-I occupied the same invagination areas, andeven they were placed at a similar distance from the lipid bilayer(Figs. 5, 6, and S1 A).

View this table:
[in this window]
[in a new window]

Table IV. Homogeneity analysis for the GRP, GDIT, GDPM, and GDLB parameters using the Kruskal-Wallis test for the indicated Myo5p and Act1p subpopulations

To investigate whether two distinct acto/myosin-I pools actuallyexist, double-labeling experiments on ultrathin sections ofyeast cells expressing HA-tagged Myo5p were performed usingthe rat monoclonal anti-HA and the mouse monoclonal anti-actinantibodies combined with 10-nm and 20-nm gold-conjugated goatanti–rat and mouse IgGs, respectively. Tight colocalizationof gold particles decorating Myo5p (10 nm) and actin (20 nm)could be observed at the base and at the tip of long invaginations(Fig. 7). Furthermore, to demonstrate that the two acto/myosin-Ipools existed in bona fide endocytic invaginations previousto the fission event, double-labeling experiments were performedfor HA-tagged Rvs167p and actin. The distal and proximal actinpools could also be demonstrated on long profiles that werealso immunodecorated for Rvs167p at the intermediate area (Fig. 7).

View larger version (95K):
[in this window]
[in a new window]
[Download PPT slide]

Figure 7. Two distinct acto/myosin-I pools associate with deep plasma membrane invaginations. Representative electron micrographs of ultrathin sections showing the colocalization of either Myo5p and Act1p or Rvs167p and Act1p. Strains expressing HA-tagged Myo5p (ScMIG994) or Rvs167p (ScMIG995) were immunolabeled with a rat anti-HA monoclonal antibody or the mouse monoclonal anti-actin antibody and the appropriate 10-nm (Myo5p and Rvs167p) and 20-nm (Act1p) gold-conjugated secondary IgGs, respectively. Bar, 100 nm.

	Discussion

Top Abstract Introduction Results Discussion Materials and methods References

In contrast to mammalian cells, ultrastructural studies on theendocytic pathway in yeast have been scarce. An early studydescribing the yeast actin cytoskeleton demonstrated plasmamembrane invaginations coated with actin and Abp1p that wereproposed as endocytic intermediates (Mulholland et al., 1994).However, the same authors failed to localize endocytic cargoon this type of membrane invagination, leaving the definitionof the primary endocytic profiles still open (Mulholland et al., 1999).

Analysis of the endocytic uptake using live cell fluorescencemicroscopy now provides tools to better interpret the electronmicroscopy results. Live cell imaging shows that assembly ofthe coat precedes sequential recruitment of all other proteinsinvolved in the process (Kaksonen et al., 2003, 2005; Jonsdottir and Li, 2004;Newpher et al., 2005; Sun et al., 2006). The data also demonstratethat the coat remains associated with the vesicles until itmoves into the cytosol (Kaksonen et al., 2003). Accordingly,plasma membrane invaginations labeled for the endocytic coatnecessarily represent the primary endocytic profiles. Immunolabelingof Sla1p, Pan1p, and clathrin on ultrathin sections demonstratedthat the primary endocytic profiles in yeast are tubular invaginationsof $~$ 50 nm and up to 180 nm in length, which are often surroundedby an electron-dense material. Not only the gold against theseproteins decorated the same type of profiles, but also, consistentwith the view that Sla1p, Chc1p, and Pan1p form an endocyticcoat, the distribution of particles along the membrane profileswas remarkably similar (Fig. 3, Fig. 8, and Table III). Morethan 95% of the gold particles labeling the endocytic coat (n= 360) were found at <50 nm from the invagination tip. Becausethe distance of the gold particle to the actual antigen is $~$ 20nm (Hermann et al., 1996), our data suggest that the endocyticcoat roughly occupies the first 30 nm from the invaginationtip.

View larger version (23K):
[in this window]
[in a new window]
[Download PPT slide]

Figure 8. Comparative distribution of endocytic proteins along short, intermediate, and long plasma membrane–associated invaginations. The graphs represent the relative frequency of immunogold associated with the indicated proteins on short (IL $≤$ 50 nm), intermediate (50 nm < IL $≤$ 100 nm), and long (IL > 100 nm) profiles normalized for the Sla1p gold subpopulations associated with those profiles binned according to their GRP. Immunogold particles were binned according to their association with the indicated areas and normalized to the Sla1p n_s, n_m, and n_l sample sizes (Fig. 3) for comparison. The number of immunogold particles decorating Act1p and Myo5p was first multiplied by the correction factor (120/180) to equal the sample size. A scheme illustrating the different invagination areas is shown in which the levels of the invagination tip (IT) and the basal plasma membrane (PM) are represented as vertical lines. Immunogold-labeled ultrathin sections were prepared as described in Fig. 1.

Live cell imaging also demonstrates that the endocytic coattravels unidirectional into the cytosol concomitant with thesequential recruitment of all other endocytic modules (Kaksonen et al., 2003).Interestingly, we found that the frequency of gold labelingthe different endocytic proteins binned according to the lengthof the associated invagination recapitulated their temporalpattern of recruitment to the cortical patch (Figs. 2 and Figs.8;Kaksonen et al., 2003, 2005; Jonsdottir and Li, 2004; Newpher et al., 2005;Sun et al., 2006). This indicates that invaginations of increasinglength represent progressively more mature endocytic profiles.Accordingly, the observation that small invaginations were practicallydevoid of particles decorating proteins recruited during theslow inward movement implies that initial membrane bending occursat some point during the immotile phase and, thus, before massiveactin polymerization. Initial membrane curvature in yeast mightrequire the epsin N-terminal homology domains of some coat componentsand/or clathrin polymerizing in a scaffold, as proposed forclathrin-dependent budding in mammalian cells (Hurley and Wendland, 2002;Hinrichsen et al., 2006).

A molecular model was recently proposed to explain actin-drivenmembrane invagination during endocytic uptake in yeast (Kaksonen et al., 2006).According to the model, the strongest actin-nucleating promotingfactors, Myo5p and Las17p, would concentrate at the rim of preassembledendocytic coated pits. Attachment of actin filaments to theendocytic coat together with continuous nucleation of actinat the plasma membrane would then push the pit inwards and leadto the formation of a tubular invagination. Our observations(1) that the primary endocytic profiles are tubular invaginationsthat accumulate the coat components at the tip, (2) that a slightlybended coated pit is probably formed before initiation of theslow inward movement, (3) that actin forms a loose cloud aroundthe endocytic coat, and (4) that Myo5p accumulates at the invaginationbase are in striking agreement with the proposed model.

However, in the context of that model, it was unexpected tofind that Las17p labeling did not concentrate at the base ofthe invagination but rather distributed along the intermediatearea (Figs. 1, Figs.6, and Figs.8). Furthermore, we found thatthe distribution of Las17p on invaginations longer than 50 nmvery much resembled that of Bbc1p (Figs. 6 and Figs.8 and Table III),suggesting that the nucleating activity of Las17p might be switchedoff by association with Bbc1p at this stage (Rodal et al., 2003;Sun et al., 2006). Accordingly, Myo5p has been shown to be theprimary Arp2/3p activator during the slow inward movement (Sun et al., 2006).

Las17p-induced actin polymerization could play a major roleprevious to Bbc1p recruitment. An interesting possibility isthat Las17p promotes initial assembly of a disordered actinnetwork on the surface of the coated pit, which is then linkedto the endocytic coat and serves as an anchoring scaffold fora more productive burst of actin polymerization organized byMyo5p at the profile base. Consistent with a role of Las17pcontrolling the onset of the slow inward movement rather thanin promoting actin polymerization at this stage, it was shownthat deletion of the Las17p domains required for its nucleatingactivity does not abolish but rather delays membrane invagination(Sun et al., 2006).

Our ultrastructural experiments now clarify some similaritiesand differences between the clathrin-dependent endocytic uptakein mammalians and yeast. Clathrin-dependent endocytosis in highereukaryotes involves the formation of a spherical constrictedpit stabilized by a clathrin lattice. In yeast, although a partiallycurved endocytic coat is probably assembled, clathrin polymerizationfails to drive constriction of the incipient pit. Instead, anactin-based mechanism that involves the formation of a tubularprofile is in charge of completing budding. The structure ofthe yeast clathrin might preclude its assembly into a latticeor provide insufficient force to bend the lipid bilayer. Alternatively,the thickness or the rigidity of the yeast plasma membrane mightprevent closure of the incipient coat. Interestingly, actinpolymerization and myosin-I recruitment occur on a subset offorming clathrin-coated pits in mammalian cells (Merrifield et al., 2002;Krendel et al., 2007). The lipid composition of the donor membraneand/or the nature of the endocytosed cargo might also definein mammalians the local stiffness of the lipid bilayer and,thus, the necessity for an actin-based mechanism to help membranebending or vesicle scission.

In mammalian cells, scission of clathrin-coated buds requiresthe GTPase dynamin, which may work as a regulatory enzyme and/oras a molecular motor that constricts the vesicle neck (Song and Schmid, 2003).Strikingly, dynamin does not seem to be required for endocyticuptake in yeast (Gammie et al., 1995; Yu and Cai, 2004). Ourstudy now provides important information regarding a possiblealternative mechanism for vesicle fission. Statistical analysisof the distribution of gold particle labeling actin and Myo5pand double-labeling experiments demonstrated that in long profiles,actin and myosin-I form two distinct structures separated bythe scission machinery (Fig. 8). A cooperative role for myosin-Iwith the fission machinery is consistent with our own unpublishedobservations demonstrating synthetic growth defects when combiningmutations in the yeast amphiphysins and myosins-I (unpublisheddata) and also with the observation that a point mutation inthe myosin-I lipid-binding domain causes accumulation of longplasma membrane–associated invaginated profiles in yeast(Jonsdottir and Li, 2004). The basal acto/myosin-I structuremight form a ringlike structure that either stiffens the baseof the endocytic profile or acts as a contractile ring in away similar to what has been proposed for dynamin (Song and Schmid, 2003).The observations that actin might adopt a spiral-like arrangementaround plasma membrane invaginations (Mulholland et al., 1994)and that myosin-I can cross-link and/or slide actin filaments(Pollard et al., 1991) support these hypotheses. The distalmyosin-I pool could anchor the incipient endocytic profile topreformed actin cables or to internal compartments (Toshima et al., 2006)to provide the tension necessary for scission (Roux et al., 2006).

Characterization of the distribution of other proteins requiredfor the endocytic uptake and analysis of the ultrastructureof the endocytic profiles in mutants with internalization defectsare now required to unveil the mechanism of primary endocyticbudding in yeast.

Materials and methods

Top
Abstract
Introduction
Results
Discussion
Materials and methods
References

Yeast strains and plasmid construction
The yeast strains used are listed in Table V. HA tag was fusedat the C terminus of each protein by homologous recombinationin the gene as described previously (Wach et al., 1997). PCRswere performed using a DNA polymerase with proof reading activity(Vent polymerase; New England Biolabs, Inc.). Oligonucleotideswere synthesized by MWG-Biotech AG. pMIG692 is a centromericshuttle vector based on pYCplac111 containing a C-terminal HA-taggedSLA1 gene under its own promoter and the selectable marker HIS3MX.It was constructed by homologous recombination in yeast. Unlessotherwise mentioned, strains without plasmid were grown in completeyeast peptone dextrose medium, and strains with plasmid weregrown on synthetic dextrose complete medium without leucin at26°C (Guthrie and Fink, 1991). Transformation of yeast wasaccomplished by the lithium acetate method (Ito et al., 1983).

View this table:
[in this window]
[in a new window]

Table V. Saccharomyces cerevisiae strains used in this study

Preparation of yeast ultrathin sections and immunolabeling
Cells were grown in yeast peptone dextrose medium to 4–5x 10⁶ cells/ml and harvested over a disposable Stericup 0.22-µmfilter unit with a vacuum of –20 to –15 Hg, leavingbehind 5 ml of media. 25 ml of 1.2x fixative solution was immediatelyadded to obtain final concentrations of 0.04 M KPO₄, pH 6.6,0.6 M sorbitol, 4% formaldehyde (from a 16% ethanol-free ultrapureelectron microscopy–grade solution; Polysciences, Inc.),0.4% glutaraldehyde (25% electron microscopy–grade solution;Fluka), 1 mM MgCl₂, 0.5 mM EGTA (glycol-bis[2-aminoethylether]-N,N,N',N'–tetraaceticacid), 10 mM NaF, and 10 mM KF. Cells were then transferredto a 50-ml Falcon tube (BD Biosciences), and fixation was continuedovernight at 4°C with rolling. Subsequent steps (metaperiodateand ammonium chloride treatments, dehydration, infiltration,embedding, and sectioning) were performed as described previously(Mulholland et al., 1994) without further modifications. Forimmunolabeling, ultrathin sections were incubated for 15 minin blocking buffer (10 mM KPO₄, pH 7.5, 150 mM NaCl, 2% BSA,and 0.05% Tween 20), transferred to a 25-µl drop of primaryantibody in blocking buffer for 3 h, and washed over 30 minin washing buffer (10 mM KPO₄ buffer, pH 7.5, 150 mM NaCl, and0.05% Tween 20). After blocking for 15 min, grids were incubatedwith the corresponding gold-conjugated secondary antibody for60 min and were washed first for 30 min in washing buffer andthen for a further 30 min in washing buffer without Tween 20.All steps of immunolabeling were performed at room temperature.Grids were then washed in double-distilled water and poststainedwith uranyl acetate (2% in water) over 60 min and lead citratefor 30 s as described previously (Reynolds, 1963). For doubleimmunolabeling, ultrathin sections were incubated with a mixtureof the two first antibodies for 3 h, washed as described forthe single immunolabeling, incubated with a mixture of the corresponding1:50 diluted secondary antibodies, and conjugated to gold particlesof different sizes. 8 µg/ml anti-HA rat monoclonal antibody(3F10; Roche), 200 µg/ml mouse anti-actin monoclonal antibody(C4; Chemicon International), and a mixture of six mouse anti-Chc1pmonoclonal antibodies diluted 1:5 (Lemmon et al., 1988) wereused as primary antibodies for the detection of HA-tagged proteins,actin, and clathrin, respectively (the antibodies against clathrinwere gifts from S.K. Lemmon, University of Miami, Miami, FL).20-nm gold-conjugated goat anti–mouse IgG (EM.GMHL20)and 10-nm gold-conjugated anti–rat IgG (EM.GAT10; BB International)were used as secondary antibodies (diluted 1:50). Ultrathinsections were examined using a transmission electron microscope(model 1010; JEOL) at 50 Kv accelerating voltage. Micrographsof the yeast plasma membrane invaginations were acquired at100,000x magnification with a CCD camera (MegaView III; Olympus)and image acquisition analySIS software (Olympus). Adjustmentsof image size, brightness, and contrast were performed on Photoshop5.0 (Adobe). The IL was measured on immunoelectron micrographsas the distance from a reference line that defines the basalplasma membrane to the invagination tip. The GDPM was measuredas the minimal distance from the basal plasma membrane to thecenter of the gold particle. The GDLB was measured as the minimaldistance from the gold center to the lipid bilayer. The distancemeasurements on micrographs were performed by Photoshop 5.0.2ruler.

The specificity of the anti-HA labeling on plasma membrane invaginationswas assessed for the less abundant endocytic protein Las17pat the endocytic patch and for the most transiently recruitedone, Rvs167p (Sun et al., 2006). 45% of the plasma membraneinvaginations (n_i = 200) on ultrathin sections of the strainexpressing HA-tagged Las17p (ScMIG516) were labeled with immunogoldparticles versus 12.5% of the plasma membrane invaginations(n_i = 200) on ultrathin sections of the isogenic wild type (ScMIG228).For Rvs167p, 61% of the plasma membrane invaginations (n_i =200) on ultrathin sections of the strain expressing HA-taggedRvs167p (ScMIG995) were labeled with immunogold particles versus9.5% of the plasma membrane invaginations (n_i = 200) on ultrathinsections of the isogenic wild type (ScMIG100).

Statistical analysis of the immunogold distribution
All statistical analyses of the immunogold distributions wereperformed with a statistical package for Windows (version 15.0;SPSS). A nonparametric Kruskal-Wallis test (Kruskal and Wallis, 1952)was used for comparison of the immunogold subpopulation associatedwith the intermediate (50 nm $≤$ IL < 100 nm) and long (IL $≥$ 100 nm) profiles within the same protein and for comparisonof the Act1p and Myo5p distributions in short (IL $≤$ 80 nm) andvery long (IL $≥$ 110 nm) profiles. A generalized linear model(McCullagh and Nelder, 1989) was applied for comparison of proteinsusing the IL, GRP, GDPM, and GDIT parameters. A ${chi}$ ² test (Cochran, 1954)was used to analyze the likelihood ratio between the frequenciesof gold particles decorating Myo5p or actin on the invaginationbasal, intermediate, and apical regions.

Online supplemental material
Fig. S1 shows statistical analysis of the distribution of goldparticles labeling actin and Myo5p on invaginations shorterthan 80 nm or longer than 110 nm. Table S1 shows the descriptivestatistics for the IL parameter. Table S2 shows the descriptivestatistics for the GRP, GDIT, GDPM, and GDLB parameters. Onlinesupplemental material is available at http://www.jcb.org/cgi/content/full/jcb.200708060/DC1.

Acknowledgments

We thank E. Coll, G. Martínez, and C. López-Iglesias(University of Barcelona) for electron microscopy technicalsupport, M. Pons and M. Cairó for technical assistance,A. Espinal and A. Blasco (Universidad Autónoma de Barcelona)for statistical analysis, H. Girao, S. Lemmon, T. Newpher, andB. Grosshans for critical reading of the manuscript, and S.K.Lemmon for providing material.

This work was supported by a grant from the Ministerio de Educacióny Ciencia (MEC; grant BUF2005-04089). H. Grotsch is a recipientof a predoctoral fellowship from the Generalitat de Catalunya.F.-Z. Idrissi is a recipient of the Ramón y Cajal postdoctoralcontract from the MEC. I.M. Fernandez-Golbano is a recipientof a predoctoral fellowship from the MEC.

Submitted: 7 August 2007

Accepted: 13 February 2008

References

Top
Abstract
Introduction
Results
Discussion
Materials and methods
References

Anderson, B.L., I. Boldogh, M. Evangelista, C. Boone, L.A. Greene, and L.A. Pon. 1998. The Src homology domain 3 (SH3) of a yeast type I myosin, Myo5p, binds to verprolin and is required for targeting to sites of actin polarization. J. Cell Biol. 141:1357–1370.[Abstract/Free Full Text]

Cochran, W.G. 1954. Some methods for strengthening the common ${chi}$ ² tests. Biometrics. 10:417–451.[Medline]

Drees, B.L., B. Sundin, E. Brazeau, J.P. Caviston, G.C. Chen, W. Guo, K.G. Kozminski, M.W. Lau, J.J. Moskow, A. Tong, et al. 2001. A protein interaction map for cell polarity development. J. Cell Biol. 154:549–571.[Abstract/Free Full Text]

Engqvist-Goldstein, A.E., and D.G. Drubin. 2003. Actin assembly and endocytosis: from yeast to mammals. Annu. Rev. Cell Dev. Biol. 19:287–332.[CrossRef][Medline]

Gammie, A.E., L.J. Kurihara, R.B. Vallee, and M.D. Rose. 1995. DNM1, a dynamin-related gene, participates in endosomal trafficking in yeast. J. Cell Biol. 130:553–566.[Abstract/Free Full Text]

Geli, M.I., R. Lombardi, B. Schmelzl, and H. Riezman. 2000. An intact SH3 domain is required for myosin I-induced actin polymerization. EMBO J. 19:4281–4291.[CrossRef][Medline]

Guthrie, C., and G.R. Fink. 1991. Guide to Yeast Genetics and Molecular Biology (Methods in Enzymology). Vol. 194. Academic Press Inc., San Diego, CA. 933 pp.

Hermann, R., P. Walther, and M. Muller. 1996. Immunogold labeling in scanning electron microscopy. Histochem. Cell Biol. 106:31–39.[Medline]

Hinrichsen, L., A. Meyerholz, S. Groos, and E.J. Ungewickell. 2006. Bending a membrane: how clathrin affects budding. Proc. Natl. Acad. Sci. USA. 103:8715–8720.[Abstract/Free Full Text]

Huckaba, T.M., A.C. Gay, L.F. Pantalena, H.C. Yang, and L.A. Pon. 2004. Live cell imaging of the assembly, disassembly, and actin cable-dependent movement of endosomes and actin patches in the budding yeast, Saccharomyces cerevisiae. J. Cell Biol. 167:519–530.[Abstract/Free Full Text]

Hurley, J.H., and B. Wendland. 2002. Endocytosis: driving membranes around the bend. Cell. 111:143–146.[CrossRef][Medline]

Ito, H., Y. Fukuda, K. Murata, and A. Kimura. 1983. Transformation of intact yeast cells treated with alkali cations. J. Bacteriol. 153:163–168.[Abstract/Free Full Text]

Jonsdottir, G.A., and R. Li. 2004. Dynamics of yeast Myosin I: evidence for a possible role in scission of endocytic vesicles. Curr. Biol. 14:1604–1609.[CrossRef][Medline]

Kaksonen, M., Y. Sun, and D.G. Drubin. 2003. A pathway for association of receptors, adaptors, and actin during endocytic internalization. Cell. 115:475–487.[CrossRef][Medline]

Kaksonen, M., C.P. Toret, and D.G. Drubin. 2005. A modular design for the clathrin- and actin-mediated endocytosis machinery. Cell. 123:305–320.[CrossRef][Medline]

Kaksonen, M., C.P. Toret, and D.G. Drubin. 2006. Harnessing actin dynamics for clathrin-mediated endocytosis. Nat. Rev. Mol. Cell Biol. 7:404–414.[CrossRef][Medline]

Krendel, M., E.K. Osterweil, and M.S. Mooseker. 2007. Myosin 1E interacts with synaptojanin-1 and dynamin and is involved in endocytosis. FEBS Lett. 581:644–650.[CrossRef][Medline]

Kruskal, W.H., and W.A. Wallis. 1952. Use of ranks in one-criterion variance analysis. J. Amer. Statis. Assoc. 47:583–621.[CrossRef]

Lechler, T., A. Shevchenko, and R. Li. 2000. Direct involvement of yeast type I myosins in Cdc42-dependent actin polymerization. J. Cell Biol. 148:363–373.[Abstract/Free Full Text]

Lemmon, S., V.P. Lemmon, and E.W. Jones. 1988. Characterization of yeast clathrin and anticlathrin heavy-chain monoclonal antibodies. J. Cell. Biochem. 36:329–340.[CrossRef][Medline]

McCullagh, P., and J.A. Nelder. 1989. Generalized Linear Models. Second edition. Chapman and Hall, New York. 511 pp.

Merrifield, C.J., M.E. Feldman, L. Wan, and W. Almers. 2002. Imaging actin and dynamin recruitment during invagination of single clathrin-coated pits. Nat. Cell Biol. 4:691–698.[CrossRef][Medline]

Mochida, J., T. Yamamoto, K. Fujimura-Kamada, and K. Tanaka. 2002. The novel adaptor protein, Mti1p, and Vrp1p, a homolog of Wiskott-Aldrich syndrome protein-interacting protein (WIP), may antagonistically regulate type I myosins in Saccharomyces cerevisiae. Genetics. 160:923–934.[Abstract/Free Full Text]

Mulholland, J., D. Preuss, A. Moon, A. Wong, D. Drubin, and D. Botstein. 1994. Ultrastructure of the yeast actin cytoskeleton and its association with the plasma membrane. J. Cell Biol. 125:381–391.[Abstract/Free Full Text]

Mulholland, J., J. Konopka, B. Singer-Kruger, M. Zerial, and D. Botstein. 1999. Visualization of receptor-mediated endocytosis in yeast. Mol. Biol. Cell. 10:799–817.[Abstract/Free Full Text]

Newpher, T.M., R.P. Smith, V. Lemmon, and S.K. Lemmon. 2005. In vivo dynamics of clathrin and its adaptor-dependent recruitment to the actin-based endocytic machinery in yeast. Dev. Cell. 9:87–98.[CrossRef][Medline]

Pollard, T.D., S.K. Doberstein, and H.G. Zot. 1991. Myosin-I. Annu. Rev. Physiol. 53:653–681.[CrossRef][Medline]

Reynolds, E.S. 1963. The use of lead citrate at high pH as an electron-opaque stain in electron microscopy. J. Cell Biol. 17:208–212.[Free Full Text]

Rodal, A.A., A.L. Manning, B.L. Goode, and D.G. Drubin. 2003. Negative regulation of yeast WASp by two SH3 domain-containing proteins. Curr. Biol. 13:1000–1008.[CrossRef][Medline]

Rodal, A.A., L. Kozubowski, B.L. Goode, D.G. Drubin, and J.H. Hartwig. 2005. Actin and septin ultrastructures at the budding yeast cell cortex. Mol. Biol. Cell. 16:372–384.[Abstract/Free Full Text]

Roux, A., K. Uyhazi, A. Frost, and P. De Camilli. 2006. GTP-dependent twisting of dynamin implicates constriction and tension in membrane fission. Nature. 441:528–531.[CrossRef][Medline]

Song, B.D., and S.L. Schmid. 2003. A molecular motor or a regulator? Dynamin's in a class of its own. Biochemistry. 42:1369–1376.[CrossRef][Medline]

Sun, Y., A.C. Martin, and D.G. Drubin. 2006. Endocytic internalization in budding yeast requires coordinated actin nucleation and myosin motor activity. Dev. Cell. 11:33–46.[CrossRef][Medline]

Sun, Y., S. Carroll, M. Kaksonen, J.Y. Toshima, and D.G. Drubin. 2007. PtdIns(4,5)P2 turnover is required for multiple stages during clathrin- and actin-dependent endocytic internalization. J. Cell Biol. 177:355–367.[Abstract/Free Full Text]

Toshima, J.Y., J. Toshima, M. Kaksonen, A.C. Martin, D.S. King, and D.G. Drubin. 2006. Spatial dynamics of receptor-mediated endocytic trafficking in budding yeast revealed by using fluorescent alpha-factor derivatives. Proc. Natl. Acad. Sci. USA. 103:5793–5798.[Abstract/Free Full Text]

Wach, A., A. Brachat, C. Alberti-Segui, C. Rebischung, and P. Philippsen. 1997. Heterologous HIS3 marker and GFP reporter modules for PCR-targeting in Saccharomyces cerevisiae. Yeast. 13:1065–1075.[CrossRef][Medline]

Yu, X., and M. Cai. 2004. The yeast dynamin-related GTPase Vps1p functions in the organization of the actin cytoskeleton via interaction with Sla1p. J. Cell Sci. 117:3839–3853.[Abstract/Free Full Text]

CiteULike

Complore

Connotea

Del.icio.us Add to Digg

Digg

Facebook

Technorati

Twitter What's this?

Related Article

Taking apart the endocytic machinery: Marko Kaksonen
J. Cell Biol. 2008 180: 1059-1060. [Abstract] [Full Text] [PDF]

This article has been cited by other articles:

Stradalova, V., Stahlschmidt, W., Grossmann, G., Blazikova, M., Rachel, R., Tanner, W., Malinsky, J. (2009). Furrow-like invaginations of the yeast plasma membrane correspond to membrane compartment of Can1. J. Cell Sci. 122: 2887-2894 [Abstract] [Full Text]
Kaksonen, M. (2008). Taking apart the endocytic machinery. JCB 180: 1059-1060 [Abstract] [Full Text]

This Article

	Abstract
	Full Text (PDF, 4106K)
	PPT slides of all figures
	Supplemental Material Index
	Alert me when this article is cited
	Citation Map

Services

	Email this article
	Similar articles in this journal
	Similar articles in PubMed
	Alert me to new content in the JCB
	Download to citation manager

Citing Articles

	Citing Articles via HighWire
	Citing Articles via CrossRef
	Citing Articles via Google Scholar

Google Scholar

	Articles by Idrissi, F.-Z.
	Articles by Geli, M.-I.
	Search for Related Content

PubMed

	PubMed Citation
	Articles by Idrissi, F.-Z.
	Articles by Geli, M.-I.


Related Collections

	Related Article

Social Bookmarking

	What's this?