The function of the endocytic scaffold protein Pan1p depends on multiple domains

Pan1p is an essential protein of the yeast Saccharomyces cerevisiae that is required for the internalization step of endocytosis and organization of the actin cytoskeleton. Pan1p, which binds several other endocytic proteins, is composed of multiple protein-protein interaction domains including two Eps15 Homology (EH) domains, a coiled-coil domain, an acidic Arp2/3-activating region, and a proline-rich domain. In this study, we have induced high-level expression of various domains of Pan1p in wild-type cells to assess the dominant consequences on viability, endocytosis, and actin organization. We found that the most severe phenotypes, with blocked endocytosis and aggregated actin, required expression of nearly full length Pan1p, and also required the endocytic regulatory protein kinase Prk1p. The central coiled-coil domain was the smallest fragment whose overexpression caused any dominant effects; these effects were more pronounced by inclusion of the second EH domain. Co-overexpressing nonoverlapping amino- and carboxy-terminal fragments did not mimic the effects of the intact protein, whereas fragments that overlapped within the coiled-coil region could. Yeast two-hybrid and in vivo coimmunoprecipitation analyses suggest that Pan1 may form dimers or higher order oligomers. Collectively, our data support a view of Pan1p as a dimeric/oligomeric scaffold whose functions require both the amino- and carboxy-termini, linked by the central region.     

Pan1 is an intrinsically disordered protein with homotypic interactions

The yeast scaffold protein Pan1 contains two EH domains at its N‐terminus, a predicted coiled‐coil central region, and a C‐terminal proline‐rich domain. Pan1 is also predicted to contain regions of intrinsic disorder, characteristic of proteins that have many binding partners. In vitro biochemical data suggest that Pan1 exists as a dimer, and we have identified amino acids 705 to 848 as critical for this homotypic interaction. Tryptophan fluorescence was used to further characterize Pan1 conformational states. Pan1 contains four endogenous tryptophans, each in a distinct region of the protein: Trp³¹² and Trp⁶⁴² are each in an EH domain, Trp⁹⁵⁷ is in the central region, and Trp¹²⁸⁰ is a critical residue in the Arp2/3 activation domain. To examine the local environment of each of these tryptophans, three of the four tryptophans were mutagenized to phenylalanine to create four proteins, each with only one tryptophan residue. When quenched with acrylamide, these single tryptophan mutants appeared to undergo collisional quenching exclusively and were moderately accessible to the acrylamide molecule. Quenching with iodide or cesium, however, revealed different Stern‐Volmer constants due to unique electrostatic environments of the tryptophan residues. Time‐resolved fluorescence anisotropy data confirmed structural and disorder predictions of Pan1. Further experimentation to fully develop a model of Pan1 conformational dynamics will assist in a deeper understanding of the mechanisms of endocytosis. Proteins 2013; 81:1944–1963. © 2013 Wiley Periodicals, Inc.     

Regulation of clathrin coat assembly by Eps15 homology domain-mediated interactions during endocytosis

Clathrin-mediated endocytosis involves a coordinated series of molecular events regulated by interactions among a variety of proteins and lipids through specific domains. One such domain is the Eps15 homology (EH) domain, a highly conserved protein-protein interaction domain present in a number of proteins distributed from yeast to mammals. Several lines of evidence suggest that the yeast EH domain-containing proteins Pan1p, End3p, and Ede1p play important roles during endocytosis. Although genetic and cell-biological studies of these proteins suggested a role for the EH domains in clathrin-mediated endocytosis, it was unclear how they regulate clathrin coat assembly. To explore the role of the EH domain in yeast endocytosis, we mutated those of Pan1p, End3p, or Ede1p, respectively, and examined the effects of single, double, or triple mutation on clathrin coat assembly. We found that mutations of the EH domain caused a defect of cargo internalization and a delay of clathrin coat assembly but had no effect on assembly of the actin patch. We also demonstrated functional redundancy among the EH domains of Pan1p, End3p, and Ede1p for endocytosis. Of interest, the dynamics of several endocytic proteins were differentially affected by various EH domain mutations, suggesting functional diversity of each EH domain.     

Structural insight into the interaction of proteins containing NPF,DPF, and GPF motifs with the C‐terminal EH‐domain of EHD1

Eps15 homology (EH)‐domain containing proteins are regulators of endocytic membrane trafficking. EH‐domain binding to proteins containing the tripeptide NPF has been well characterized, but recent studies have shown that EH‐domains are also able to interact with ligands containing DPF or GPF motifs. We demonstrate that the three motifs interact in a similar way with the EH‐domain of EHD1, with the NPF motif having the highest affinity due to the presence of an intermolecular hydrogen bond. The weaker affinity for the DPF and GPF motifs suggests that if complex formation occurs in vivo, they may require high ligand concentrations, the presence of successive motifs and/or specific flanking residues.     

PTRN‐1/CAMSAP promotes CYK‐1/formin‐dependent actin polymerization during endocytic recycling

Cargo sorting and membrane carrier initiation in recycling endosomes require appropriately coordinated actin dynamics. However, the mechanism underlying the regulation of actin organization during recycling transport remains elusive. Here we report that the loss of PTRN‐1/CAMSAP stalled actin exchange and diminished the cytosolic actin structures. Furthermore, we found that PTRN‐1 is required for the recycling of clathrin‐independent cargo hTAC‐GFP. The N‐terminal calponin homology (CH) domain and central coiled‐coils (CC) region of PTRN‐1 can synergistically sustain the flow of hTAC‐GFP. We identified CYK‐1/formin as a binding partner of PTRN‐1. The N‐terminal GTPase‐binding domain (GBD) of CYK‐1 serves as the binding interface for the PTRN‐1 CH domain. The presence of the PTRN‐1 CH domain promoted CYK‐1‐mediated actin polymerization, which suggests that the PTRN‐1‐CH:CYK‐1‐GBD interaction efficiently relieves autoinhibitory interactions within CYK‐1. As expected, the overexpression of the CYK‐1 formin homology domain 2 (FH2) substantially restored actin structures and partially suppressed the hTAC‐GFP overaccumulation phenotype in ptrn‐1 mutants. We conclude that the PTRN‐1 CH domain is required to stimulate CYK‐1 to facilitate actin dynamics during endocytic recycling.     

Calmodulin dissociation regulates Myo5 recruitment and function at endocytic sites

Myosins‐I are conserved proteins that bear an N‐terminal motor head followed by a Tail Homology 1 (TH1) lipid‐binding domain. Some myosins‐I have an additional C‐terminal extension (C_ext) that promotes Arp2/3 complex‐dependent actin polymerization. The head and the tail are separated by a neck that binds calmodulin or calmodulin‐related light chains. Myosins‐I are known to participate in actin‐dependent membrane remodelling. However, the molecular mechanisms controlling their recruitment and their biochemical activities in vivo are far from being understood. In this study, we provided evidence suggesting the existence of an inhibitory interaction between the TH1 domain of the yeast myosin‐I Myo5 and its C_ext. The TH1 domain prevented binding of the Myo5 C_ext to the yeast WIP homologue Vrp1, Myo5 C_ext‐induced actin polymerization and recruitment of the Myo5 C_ext to endocytic sites. Our data also indicated that calmodulin dissociation from Myo5 weakened the interaction between the neck and TH1 domains and the C_ext. Concomitantly, calmodulin dissociation triggered Myo5 binding to Vrp1, extended the myosin‐I lifespan at endocytic sites and activated Myo5‐induced actin polymerization.     

Distinctive Conformation of Minor Site‐Specific Nuclear Localization Signals Bound to Importin‐α

Nuclear localization signals (NLSs) contain one or two clusters of basic residues and are recognized by the import receptor importin‐α. There are two NLS‐binding sites (major and minor) on importin‐α and the major NLS‐binding site is considered to be the primary binding site. Here, we used crystallographic and biochemical methods to investigate the binding between importin‐α and predicted ‘minor site‐specific’ NLSs: four peptide library‐derived peptides, and the NLS from mouse RNA helicase II/Guα. The crystal structures reveal that these atypical NLSs indeed preferentially bind to the minor NLS‐binding site. Unlike previously characterized NLSs, the C‐terminal residues of these NLSs form an α‐helical turn, stabilized by internal H‐bond and cation‐π interactions between the aromatic residues from the NLSs and the positively charged residues from importin‐α. This helical turn sterically hinders binding at the major NLS‐binding site, explaining the minor‐site preference. Our data suggest the sequence RXXKR[K/X][F/Y/W]XXAF as the optimal minor NLS‐binding site‐specific motif, which may help identify novel proteins with atypical NLSs .     

Eng2 Is a Component of a Dynamic Protein Complex Required for Endocytic Uptake in Fission Yeast

Eng2 is a glucanase required for spore release, although it is also expressed during vegetative growth, suggesting that it might play other cellular functions. Its homology to the Saccharomyces cerevisiae Acf2 protein, previously shown to promote actin polymerization at endocytic sites in vitro, prompted us to investigate its role in endocytosis. Interestingly, depletion of Eng2 caused profound defects in endocytic uptake, which were not due to the absence of its glucanase activity. Analysis of the dynamics of endocytic proteins by fluorescence microscopy in the eng2Δ strain unveiled a previously undescribed phenotype, in which assembly of the Arp2/3 complex appeared uncoupled from the internalization of the endocytic coat and resulted in a fission defect. Strikingly also, we found that Eng2‐GFP dynamics did not match the pattern of other endocytic proteins. Eng2‐GFP localized to bright cytosolic spots that moved around the cellular poles and occasionally contacted assembling endocytic patches just before recruitment of Wsp1, the Schizosaccharomyces pombe WASP. Interestingly, Csh3‐YFP, a WASP‐interacting protein, interacted with Eng2 by co‐immunoprecipitation and was recruited to Eng2 in bright cytosolic spots. Altogether, our work defines a novel endocytic functional module, which probably couples the endocytic coat to the actin module.      

A Pan1/End3/Sla1 complex links Arp2/3-mediated actin assembly to sites of clathrin-mediated endocytosis

More than 60 highly conserved proteins appear sequentially at sites of clathrin-mediated endocytosis in yeast and mammals. The yeast Eps15-related proteins Pan1 and End3 and the CIN85-related protein Sla1 are known to interact with each other in vitro, and they all appear after endocytic-site initiation but before endocytic actin assembly, which facilitates membrane invagination/scission. Here we used live-cell imaging in parallel with genetics and biochemistry to explore comprehensively the dynamic interactions and functions of Pan1, End3, and Sla1. Our results indicate that Pan1 and End3 associate in a stable manner and appear at endocytic sites before Sla1. The End3 C-terminus is necessary and sufficient for its cortical localization via interaction with Pan1, whereas the End3 N-terminus plays a crucial role in Sla1 recruitment. We systematically examined the dynamic behaviors of endocytic proteins in cells in which Pan1 and End3 were simultaneously eliminated, using the auxin-inducible degron system. The results lead us to propose that endocytic-site initiation and actin assembly are separable processes linked by a Pan1/End3/Sla1 complex. Finally, our study provides mechanistic insights into how Pan1 and End3 function with Sla1 to coordinate cargo capture with actin assembly.     

Structural basis for Pan3 binding to Pan2 and its function in mRNA recruitment and deadenylation

The conserved eukaryotic Pan2–Pan3 deadenylation complex shortens cytoplasmic mRNA 3′ polyA tails to regulate mRNA stability. Although the exonuclease activity resides in Pan2, efficient deadenylation requires Pan3. The mechanistic role of Pan3 is unclear. Here, we show that Pan3 binds RNA directly both through its pseudokinase/C‐terminal domain and via an N‐terminal zinc finger that binds polyA RNA specifically. In contrast, isolated Pan2 is unable to bind RNA. Pan3 binds to the region of Pan2 that links its N‐terminal WD40 domain to the C‐terminal part that contains the exonuclease, with a 2:1 stoichiometry. The crystal structure of the Pan2 linker region bound to a Pan3 homodimer shows how the unusual structural asymmetry of the Pan3 dimer is used to form an extensive high‐affinity interaction. This binding allows Pan3 to supply Pan2 with substrate polyA RNA, facilitating efficient mRNA deadenylation by the intact Pan2–Pan3 complex.     

The dense‐core vesicle maturation protein CCCP‐1 binds RAB‐2 and membranes through its C‐terminal domain

Dense‐core vesicles (DCVs) are secretory organelles that store and release modulatory neurotransmitters from neurons and endocrine cells. Recently, the conserved coiled‐coil protein CCCP‐1 was identified as a component of the DCV biogenesis pathway in the nematode Caenorhabditis elegans. CCCP‐1 binds the small GTPase RAB‐2 and colocalizes with it at the trans‐Golgi. Here, we report a structure‐function analysis of CCCP‐1 to identify domains of the protein important for its localization, binding to RAB‐2, and function in DCV biogenesis. We find that the CCCP‐1 C‐terminal domain (CC3) has multiple activities. CC3 is necessary and sufficient for CCCP‐1 localization and for binding to RAB‐2, and is required for the function of CCCP‐1 in DCV biogenesis. In addition, CCCP‐1 binds membranes directly through its CC3 domain, indicating that CC3 may comprise a previously uncharacterized lipid‐binding motif. We conclude that CCCP‐1 is a coiled‐coil protein that binds an activated Rab and localizes to the Golgi via its C‐terminus, properties similar to members of the golgin family of proteins. CCCP‐1 also shares biophysical features with golgins; it has an elongated shape and forms oligomers.      

Crystal structure and nucleic acid‐binding activity of the CRISPR‐associated protein Csx1 of Pyrococcus furiosus

In many prokaryotic organisms, chromosomal loci known as clustered regularly interspaced short palindromic repeats (CRISPRs) and CRISPR‐associated (CAS) genes comprise an acquired immune defense system against invading phages and plasmids. Although many different Cas protein families have been identified, the exact biochemical functions of most of their constituents remain to be determined. In this study, we report the crystal structure of PF1127, a Cas protein of Pyrococcus furiosus DSM 3638 that is composed of 480 amino acids and belongs to the Csx1 family. The C‐terminal domain of PF1127 has a unique β‐hairpin structure that protrudes out of an α‐helix and contains several positively charged residues. We demonstrate that PF1127 binds double‐stranded DNA and RNA and that this activity requires an intact β‐hairpin and involve the homodimerization of the protein. In contrast, another Csx1 protein from Sulfolobus solfataricus P2 that is composed of 377 amino acids does not have the β‐hairpin structure and exhibits no DNA‐binding properties under the same experimental conditions. Notably, the C‐terminal domain of these two Csx1 proteins is greatly diversified, in contrast to the conserved N‐terminal domain, which appears to play a common role in the homodimerization of the protein. Thus, although P. furiosus Csx1 is identified as a nucleic acid‐binding protein, other Csx1 proteins are predicted to exhibit different individual biochemical activities. Proteins 2013. © 2012 Wiley Periodicals, Inc.     

Pan1p, End3p, and S1a1p, three yeast proteins required for normal cortical actin cytoskeleton organization, associate with each other and play essential roles in cell wall morphogenesis

The EH domain proteins Pan1p and End3p of budding yeast have been known to form a complex in vivo and play important roles in organization of the actin cytoskeleton and endocytosis. In this report, we describe new findings concerning the function of the Pan1p-End3p complex. First, we found that the Pan1p-End3p complex associates with Sla1p, another protein known to be required for the assembly of cortical actin structures. Sla1p interacts with the first long repeat region of Pan1p and the N-terminal EH domain of End3p, thus leaving the Pan1p-End3p interaction, which requires the second long repeat of Pan1p and the C-terminal repeat region of End3p, undisturbed. Second, Pan1p, End3p, and Sla1p are also required for normal cell wall morphogenesis. Each of the Pan1-4, sla1Delta, and end3Delta mutants displays the abnormal cell wall morphology previously reported for the act1-1 mutant. These cell wall defects are also exhibited by wild-type cells overproducing the C-terminal region of Sla1p that is responsible for interactions with Pan1p and End3p. These results indicate that the functions of Pan1p, End3p, and Sla1p in cell wall morphogenesis may depend on the formation of a heterotrimeric complex. Interestingly, the cell wall abnormalities exhibited by these cells are independent of the actin cytoskeleton organization on the cell cortex, as they manifest despite the presence of apparently normal cortical actin cytoskeleton. Examination of several act1 mutants also supports this conclusion. These observations suggest that the Pan1p-End3p-Sla1p complex is required not only for normal actin cytoskeleton organization but also for normal cell wall morphogenesis in yeast.     

GSK‐3β Phosphorylation of Cytoplasmic Dynein Reduces Ndel1 Binding to Intermediate Chains and Alters Dynein Motility

Glycogen synthase kinase 3 (GSK‐3) has been linked to regulation of kinesin‐dependent axonal transport in squid and flies, and to indirect regulation of cytoplasmic dynein. We have now found evidence for direct regulation of dynein by mammalian GSK‐3β in both neurons and non‐neuronal cells. GSK‐3β coprecipitates with and phosphorylates mammalian dynein. Phosphorylation of dynein intermediate chain (IC) reduces its interaction with Ndel1, a protein that contributes to dynein force generation. Two conserved residues, S87/T88 in IC‐1B and S88/T89 in IC‐2C, have been identified as GSK‐3 targets by both mass spectrometry and site‐directed mutagenesis. These sites are within an Ndel1‐binding domain, and mutation of both sites alters the interaction of IC's with Ndel1. Dynein motility is stimulated by (i) pharmacological and genetic inhibition of GSK‐3β, (ii) an insulin‐sensitizing agent (rosiglitazone) and (iii) manipulating an insulin response pathway that leads to GSK‐3β inactivation. Thus, our study connects a well‐characterized insulin‐signaling pathway directly to dynein stimulation via GSK‐3 inhibition.      

HAI‐2 stabilizes,inhibits and regulates SEA‐cleavage‐dependent secretory transport of matriptase

It has recently been shown that hepatocyte growth factor activator inhibitor‐2 (HAI‐2) is able to suppress carcinogenesis induced by overexpression of matriptase, as well as cause regression of individual established tumors in a mouse model system. However, the role of HAI‐2 is poorly understood. In this study, we describe 3 mutations in the binding loop of the HAI‐2 Kunitz domain 1 (K42N, C47F and R48L) that cause a delay in the SEA domain cleavage of matriptase, leading to accumulation of non‐SEA domain cleaved matriptase in the endoplasmic reticulum (ER). We suggest that, like other known SEA domains, the matriptase SEA domain auto‐cleaves and reflects that correct oligomerization, maturation, and/or folding has been obtained. Our results suggest that the HAI‐2 Kunitz domain 1 mutants influence the flux of matriptase to the plasma membrane by affecting the oligomerization, maturation and/or folding of matriptase, and as a result the SEA domain cleavage of matriptase. Two of the HAI‐2 Kunitz domain 1 mutants investigated (C47F, R48L and C47F/R48L) also displayed a reduced ability to proteolytically silence matriptase. Hence, HAI‐2 separately stabilizes matriptase, regulates the secretory transport, possibly via maturation/oligomerization and inhibits the proteolytic activity of matriptase in the ER, and possible throughout the secretory pathway.      

Endocytic activity of HIV‐1 Vpu: Phosphoserine‐dependent interactions with clathrin adaptors

HIV‐1 Vpu modulates cellular transmembrane proteins to optimize viral replication and provide immune‐evasion, triggering ubiquitin‐mediated degradation of some targets but also modulating endosomal trafficking to deplete them from the plasma membrane. Interactions between Vpu and the heterotetrameric clathrin adaptor protein (AP) complexes AP‐1 and AP‐2 have been described, yet the molecular basis and functional roles of such interactions are incompletely defined. To investigate the trafficking signals encoded by Vpu, we fused the cytoplasmic domain (CD) of Vpu to the extracellular and transmembrane domains of the CD8 α‐chain. CD8‐VpuCD was rapidly endocytosed in a clathrin‐ and AP‐2‐dependent manner. Multiple determinants within the Vpu CD contributed to endocytic activity, including phosphoserines of the β‐TrCP binding site and a leucine‐based ExxxLV motif. Using recombinant proteins, we confirmed ExxxLV‐dependent binding of the Vpu CD to the α/σ2 subunit hemicomplex of AP‐2 and showed that this is enhanced by serine‐phosphorylation. Remarkably, the Vpu CD also bound directly to the medium (μ) subunits of AP‐2 and AP‐1; this interaction was dependent on serine‐phosphorylation of Vpu and on basic residues in the μ subunits. We propose that the flexibility with which Vpu binds AP complexes broadens the range of cellular targets that it can misdirect to the virus' advantage.      

Yeast Endocytic Adaptor AP‐2 Binds the Stress Sensor Mid2 and Functions in Polarized Cell Responses

The AP‐2 complex is a heterotetrameric endocytic cargo‐binding adaptor that facilitates uptake of membrane proteins during mammalian clathrin‐mediated endocytosis. While budding yeast has clear homologues of all four AP‐2 subunits which form a complex and localize to endocytic sites in vivo, the function of yeast AP‐2 has remained enigmatic. Here, we demonstrate that AP‐2 is required for hyphal growth in Candida albicans and polarized cell responses in Saccharomyces cerevisiae. Deletion of APM4, the cargo‐binding mu subunit of AP‐2, causes defects in pseudohyphal growth, generation of a mating projection and the cell wall damage response. In an apm4 null mutant, the cell wall stress sensor Mid2 is unable to relocalize to the tip of a mating projection following pheromone addition, or to the mother bud neck in response to cell wall damage. A direct binding interaction between Mid2 and the mu homology domain of Apm4 further supports a model in which AP‐2 binds Mid2 to facilitate its internalization and relocalization in response to specific signals. Thus, Mid2 is the first cargo for AP‐2 identified in yeast. We propose that endocytic recycling of Mid2 and other components is required for polarized cell responses ensuring cell wall deposition and is tightly monitored during cell growth.      

Protection against β‐amyloid neurotoxicity by a non‐toxic endogenous N‐terminal β‐amyloid fragment and its active hexapeptide core sequence

High levels (μM) of beta amyloid (Aβ) oligomers are known to trigger neurotoxic effects, leading to synaptic impairment, behavioral deficits, and apoptotic cell death. The hydrophobic C‐terminal domain of Aβ, together with sequences critical for oligomer formation, is essential for this neurotoxicity. However, Aβ at low levels (pM‐nM) has been shown to function as a positive neuromodulator and this activity resides in the hydrophilic N‐terminal domain of Aβ. An N‐terminal Aβ fragment (1–15/16), found in cerebrospinal fluid, was also shown to be a highly active neuromodulator and to reverse Aβ‐induced impairments of long‐term potentiation. Here, we show the impact of this N‐terminal Aβ fragment and a shorter hexapeptide core sequence in the Aβ fragment (Aβcore: 10–15) to protect or reverse Aβ‐induced neuronal toxicity, fear memory deficits and apoptotic death. The neuroprotective effects of the N‐terminal Aβ fragment and Aβcore on Aβ‐induced changes in mitochondrial function, oxidative stress, and apoptotic neuronal death were demonstrated via mitochondrial membrane potential, live reactive oxygen species, DNA fragmentation and cell survival assays using a model neuroblastoma cell line (differentiated NG108‐15) and mouse hippocampal neuron cultures. The protective action of the N‐terminal Aβ fragment and Aβcore against spatial memory processing deficits in amyloid precursor protein/PSEN1 (5XFAD) mice was demonstrated in contextual fear conditioning. Stabilized derivatives of the N‐terminal Aβcore were also shown to be fully protective against Aβ‐triggered oxidative stress. Together, these findings indicate an endogenous neuroprotective role for the N‐terminal Aβ fragment, while active stabilized N‐terminal Aβcore derivatives offer the potential for therapeutic application.

     

Interaction of the endocytic scaffold protein Pan1 with the type I myosins contributes to the late stages of endocytosis

The yeast endocytic scaffold Pan1 contains an uncharacterized proline-rich domain (PRD) at its carboxy (C)-terminus. We report that the pan1-20 temperature-sensitive allele has a disrupted PRD due to a frame-shift mutation in the open reading frame of the domain. To reveal redundantly masked functions of the PRD, synthetic genetic array screens with a pan1DeltaPRD strain found genetic interactions with alleles of ACT1, LAS17 and a deletion of SLA1. Through a yeast two-hybrid screen, the Src homology 3 domains of the type I myosins, Myo3 and Myo5, were identified as binding partners for the C-terminus of Pan1. In vitro and in vivo assays validated this interaction. The relative timing of recruitment of Pan1-green fluorescent protein (GFP) and Myo3/5-red fluorescent protein (RFP) at nascent endocytic sites was revealed by two-color real-time fluorescence microscopy; the type I myosins join Pan1 at cortical patches at a late stage of internalization, preceding the inward movement of Pan1 and its disassembly. In cells lacking the Pan1 PRD, we observed an increased lifetime of Myo5-GFP at the cortex. Finally, Pan1 PRD enhanced the actin polymerization activity of Myo5-Vrp1 complexes in vitro. We propose that Pan1 and the type I myosins interactions promote an actin activity important at a late stage in endocytic internalization.