Ernst J. Ungewickell

Identification of the universal cofactor (auxilin 2) in clathrin coat dissociation

Uncoating of clathrin-coated vesicles in neuronal cells requires hsc70 in concert with the cofactor auxilin which contains a J-domain as well as a domain with homology to dual specific phosphatases and tensin, known as PTEN. The question of whether an analogous factor operates in other cell types has until now remained unanswered. Here we show that it is the recently discovered and widely expressed cyclin G-associated protein kinase which fulfils the function of neuronal auxilin in hsc70-mediated clathrin coat dissociation. GAK possesses a J-domain, which stimulates the hsc70 ATPase, it competes with auxilin for clathrin binding and at sufficiently high concentrations acts as a clathrin assembly protein. Moreover, GAK binds to the gamma- and alpha-appendage domains of the adaptor proteins AP-1 and AP-2 in vitro and phosphorylates their medium chains. Cells that transiently overexpress GAK are impaired in respect of receptor-mediated endocytosis. In transfected cells clathrin is dislodged from coated pits/vesicles and co-localizes with GFP-GAK in the form of large aggregates. The cellular distribution of membrane-associated adaptors was unaffected by overexpression of GAK. Our results point to a hsc70/auxilin-based uncoating system as a ubiquitous feature of eukaryotic cells.

Effect of Clathrin Assembly Lymphoid Myeloid Leukemia Protein Depletion on Clathrin Coat Formation

The endocytic accessory clathrin assembly lymphoid myeloid leukemia protein (CALM) is the ubiquitously expressed homolog of the neuron‐specific protein AP180 that has been implicated in the retrieval of synaptic vesicle. Here, we show that CALM associates with the α‐appendage domain of the AP2 adaptor via the three peptide motifs 420DPF, 375DIF and 489FESVF and to a lesser extent with the amino‐terminal domain of the clathrin heavy chain. Reducing clathrin levels by RNA interference did not significantly affect CALM localization, but depletion of AP2 weakens its association with the plasma membrane. In cells, where CALM levels were reduced by RNA interference, AP2 and clathrin remained organized in somewhat enlarged bright fluorescent puncta. Electron microscopy showed that the depletion of CALM drastically affected the clathrin lattice structure. Round‐coated buds, which are the predominant features in control cells, were replaced by irregularly shaped buds and long clathrin‐coated tubules. Moreover, we noted an increase in the number of very small cages that formed on flat lattices. Furthermore, we noticed a redistribution of endosomal markers and AP1 in cells that were CALM depleted. Taken together, our findings indicate a critical role for CALM in the regulation and orderly progression of coated bud formation at the plasma membrane.

Reconstitution of clathrin-coated bud and vesicle formation with minimal components

During the process of clathrin-mediated endocytosis an essentially planar area of membrane has to undergo a gross deformation to form a spherical bud. Three ways have been recognized by which membranes can be induced to transform themselves locally from a planar state to one of high curvature: a change in lipid distribution between the leaflets, insertion of a protein into one leaflet and formation of a protein scaffold over the surface. Such a scaffold is spontaneously generated by clathrin. Conjectures that the attachment of clathrin was the cause of the change in curvature were challenged on theoretical grounds, and also by the discovery of a number of clathrin-associated proteins with the capacity to induce membrane curvature. We have now developed a cell-free system that has enabled us to demonstrate that clathrin polymerization alone is sufficient to generate spherical buds in a membrane. This process is reversible, as shown by the reassimilation of the buds into the planar membrane when the intra-clathrin contacts are dissociated by the chaperone Hsc70. We further show that the final step in the formation of coated vesicles ensues when clathrin-coated buds are released through the action of dynamin.

AP2 controls clathrin polymerization with a membrane-activated switch

A membrane-activated switch to bind clathrin Clathrin-mediated endocytosis—the process by which cells take up nutrients and signals within clathrin-coated vesicles—is very well understood. Kelly et al. reveal an unanticipated layer of regulation in this process. The proteins AP2 and clathrin are the major constituents of endocytic clathrin-coated vesicles. AP2 and clathrin stick together through a clathrin-binding motif in AP2. The authors now show that AP2s clathrin-binding motif is normally buried within the core of the AP2 protein. AP2 only ejects its clathrin-binding motif and recruits clathrin if it is associated with the correct cell membrane and an endocytic cargo. Science, this issue p. 459 An autoinhibitory mechanism prevents clathrin recruitment by cytosolic AP2. Clathrin-mediated endocytosis (CME) is vital for the internalization of most cell-surface proteins. In CME, plasma membrane–binding clathrin adaptors recruit and polymerize clathrin to form clathrin-coated pits into which cargo is sorted. Assembly polypeptide 2 (AP2) is the most abundant adaptor and is pivotal to CME. Here, we determined a structure of AP2 that includes the clathrin-binding β2 hinge and developed an AP2-dependent budding assay. Our findings suggest that an autoinhibitory mechanism prevents clathrin recruitment by cytosolic AP2. A large-scale conformational change driven by the plasma membrane phosphoinositide phosphatidylinositol 4,5-bisphosphate and cargo relieves this autoinhibition, triggering clathrin recruitment and hence clathrin-coated bud formation. This molecular switching mechanism can couple AP2’s membrane recruitment to its key functions of cargo and clathrin binding.

A Schwann cell‐seeded intrinsic framework and its satisfactory biocompatibility for a bioartificial nerve graft

To optimize the internal environment of a collagen nerve tube, we designed a Schwann cell‐seeded intrinsic framework and its biocompatibility was investigated. We fixed 6‐0 polyglactin woven filaments (Vicryl) or polydioxanone monofilaments (PDS) on a silicone ring in a net fashion. It was coated with matrigel and then incubated with cultured newborn or adult Schwann cells. Furthermore, we implanted 1.5‐cm‐long filament‐filled collagen tubes in a rat model. Using a live/dead fluorescent assay and electron microscopy, we found that adherent Schwann cells onto filaments remained viable and oriented longitudinally along filaments. The preliminary in vivo study indicated that a mild inflammatory reaction was present around the tube wall. However, nerve regeneration occurred around and between filaments. We concluded that the arrangement of Schwann cell columns onto filaments was achieved, mimicking Bünger bands. It was shown that the biomaterials did not impede nerve regeneration.

Chaperone Role for Proteins p618 and p892 in the Extracellular Tail Development of Acidianus Two-Tailed Virus

ABSTRACT The crenarchaeal Acidianus two-tailed virus (ATV) undergoes a remarkable morphological development, extracellularly and independently of host cells, by growing long tails at each end of a spindle-shaped virus particle. Initial work suggested that an intermediate filament-like protein, p800, is involved in this process. We propose that an additional chaperone system is required, consisting of a MoxR-type AAA ATPase (p618) and a von Willebrand domain A (VWA)-containing cochaperone, p892. Both proteins are absent from the other known bicaudavirus, STSV1, which develops a single tail intracellularly. p618 exhibits ATPase activity and forms a hexameric ring complex that closely resembles the oligomeric complex of the MoxR-like protein RavA (YieN). ATV proteins p387, p653, p800, and p892 interact with p618, and with the exception of p800, all bind to DNA. A model is proposed to rationalize the interactions observed between the different protein and DNA components and to explain their possible structural and functional roles in extracellular tail development.

Effect of Clathrin Light Chains on the Stiffness of Clathrin Lattices and Membrane Budding

Clathrin‐dependent transport processes require the polymerization of clathrin triskelia into polygonal scaffolds. Together with adapter proteins, clathrin collects cargo and induces membrane bud formation. It is not known to what extent clathrin light chains affect the structural and functional properties of clathrin lattices and the ability of clathrin to deform membranes. To address these issues, we have developed a novel procedure for analyzing clathrin lattice formation on rigid surfaces. We found that lattices can form on adaptor‐coated convex‐, planar‐ and even shallow concave surfaces, but the rate of formation and resistance to thermal dissociation of the lattice are greatly enhanced on convex surfaces. Atomic force microscopy on planar clathrin lattices demonstrates that the stiffness of the clathrin lattice is strictly dependent on light chains. The reduced stiffness of the lattice also compromised the ability of clathrin to generate coated buds on the surface of rigid liposomal membranes.

A comparison of GFP-tagged clathrin light chains with fluorochromated light chains in vivo and in vitro.

Clathrin triskelia consist of three heavy chains and three light chains (LCs). Green fluorescent protein (GFP)‐tagged LCs are widely utilized to follow the dynamics of clathrin in living cells, but whether they reflect faithfully the behavior of clathrin triskelia in cells has not been investigated yet thoroughly. As an alternative approach, we labeled purified LCs either with Alexa 488 or Cy3 dye and compared them with GFP‐tagged LC variants. Cy3‐labeled light chains (Cy3‐LCs) were microinjected into HeLa cells either directly or in association with heavy chains. Within 1–2 min the Cy3‐LC heavy chain complexes entered clathrin‐coated structures, whereas uncomplexed Cy3‐LC did not within 2 h. These findings show that no significant exchange of LCs occurs over the time–course of an endocytic cycle. To explore whether GFP‐tagged LCs behave functionally like endogenous LCs, we characterized them biochemically. Unlike wild‐type LCs, recombinant LCs with a GFP attached to either end did not efficiently inhibit clathrin assembly in vitro, whereas Cy3‐ and Alexa 488‐labeled LC behaved similar to wild‐type LCs in vitro and in vivo. Thus, fluorochromated LCs are a valuable tool for investigating the complex behavior of clathrin in living cells.

Clathrin and clathrin-accessory proteins in rat kidney cortex epithelia

Several vectorial transport routes in mammalian cells involve clathrin and associated proteins. In kidney epithelia urine production requires numerous transport processes. However, only little is known about the distribution of clathrin and its associated proteins in this organ in situ. We now report on the presence and distribution of clathrin and its accessory proteins AP1, AP2, Eps15, Epsin, CALM and Clint/EpsinR in the epithelia of the rat kidney cortex using immunoblotting, immunofluorescence and immuno-electron microscopy. Our data show that all investigated proteins are ubiquitously present in rat kidney cortex epithelia, however, with distinct distribution patterns. In the renal corpuscle, podocytes showed the most conspicuous labelling. Clathrin, AP2 and CALM were highly expressed in foot processes, while AP1 was primarily localized in the cell body. In the proximal tubule all proteins were present in dots along the plasma membrane and most conspicuous below the brush border. However, clathrin and AP2 co-localized in vesicle subtypes distinct from those containing clathrin and AP1. In the distal tubule and in the cortical collecting duct all proteins were found in the apex of the cells; however, AP1 and Clint/EpsinR showed additional staining in perinuclear dots. The occurrence and distribution of the investigated proteins in kidney epithelia are discussed with respect to their possible involvement in the functions of the specific nephron segment.