key: cord-0842368-q78ujqcs
authors: Veiga, Esteban; Cossart, Pascale
title: The role of clathrin-dependent endocytosis in bacterial internalization
date: 2006-09-08
journal: Trends Cell Biol
DOI: 10.1016/j.tcb.2006.08.005
sha: 2569a71a39c191444e15635722bf91115ea0d428
doc_id: 842368
cord_uid: q78ujqcs

Internalization of bacteria into mammalian host cells has been studied extensively in the past two decades. These studies have highlighted the amazingly diverse strategies used by bacterial pathogens to induce their entry in non-phagocytic cells. The roles of actin and of the whole cytoskeletal machinery have been investigated in great detail for several invasive organisms, such as Salmonella, Shigella, Yersinia and Listeria. Recent results using Listeria highlight a role for the endocytosis machinery in bacterial entry, suggesting that clathrin-dependent endocytic mechanisms are also involved in internalization of large particles. This contrasts with the generally accepted dogma but agrees with previous studies of bacterial and viral infections and also of phagocytosis.

The plasma membrane is a dynamic structure that separates the intracellular compartment from the extracellular milieu and enables communication between the cell and its environment. Ions and small molecules, such as amino acids and sugars, can traverse the plasma membrane through membrane channels. Macromolecules and larger structures enter cells by endocytosis, which is defined as the uptake by invagination and pinching-off of portions of the plasma membrane containing lipids and membrane proteins, extracellular ligands and/or soluble molecules [1] [2] [3] . Several types of endocytosis have been described, differing in the size of the endocytic vesicle, the nature of the cargo and the mechanism of vesicle formation. They include phagocytosis, macropinocytosis, clathrin-mediated endocytosis, caveolin-mediated endocytosis and clathrinand caveolin-independent endocytosis [1] .

Phagocytosis is restricted to 'professional phagocytes', such as neutrophils, macrophages or dendritic cells, whereas the other internalization events occur in almost all cell types. Both phagocytosis and macropinocytosis produce extensions of the plasma membrane, driven by actin polymerization, whereby cells engulf particles and/or extracellular fluid. The other entry processes have long been considered to be actin-independent events.

Clathrin-mediated endocytosis is the major process by which transmembrane proteins are internalized from the plasma membrane. It starts at the so-called coated pits, which are formed by the assembly of clathrin on the cytoplasmic side of the plasma membrane. Transmembrane proteins are selectively recruited to these coated pits by binding to clathrin adaptors or other coat-associated proteins. The coated pit then pinches off from the membrane and forms a coated vesicle inside the cell [4] . Clathrin in coated vesicles is structured as a triskelion, formed by three heavy (192 kDa) and three light (25) (26) (27) (28) (29) chains that bind to each other in a polyhedral lattice [5] . Data from in vitro reconstitution studies and models of clathrin triskelion suggest that clathrin can support the entry of vesicles with a maximal diameter of 120 nm [6] [7] [8] . This led to the dogma that particles with a diameter larger that 120 nm cannot enter cells by clathrin-mediated endocytosis [1] . In addition to enabling the entry of macromolecules (e.g. low density lipoprotein, a2 macroglobulin or growth factor receptors), clathrin-mediated endocytosis is a well documented portal of entry for a large number of viruses (e.g. influenza viruses, adenoviruses, vesicular stomatitis virus (VSV), reoviruses, Semliki forest virus, Ebola virus, SARS coronavirus or hepatitis B and C viruses) to invade host cells [9] [10] [11] [12] [13] [14] .

Invasive bacteria, like viruses, induce their own uptake by non-phagocytic host cells. In this intracellular niche, bacteria are protected from hostile events occurring in the extracellular environment, such as complement deposition or antibody binding. They can then multiply and invade neighbouring cells after direct cell-to-cell spread or after cell lysis. Invasive bacteria can be separated into two welldifferentiated groups on the basis of their entry mechanisms, the 'zipper' and the 'trigger' mechanisms (Box 1). The entry of Listeria monocytogenes, Yersinia pseudotuberculosis and other pathogenic bacteria that invade host cells by the zipper mechanism is triggered by the interactions between bacterial surface-exposed proteins and cellular receptors. For example, the Listeria proteins InlA and InlB interact with cellular E-cadherin (an adhesion protein) and Met (also known as hepatocyte growth factor (HGF) receptor), respectively, and Yersinia invasin binds to b1-integrins. These interactions induce signalling cascades that result in the activation of the actin cytoskeleton and relatively small membrane extensions that zip around the bacterium and engulf it [15] . Salmonella and Shigella are the paradigms of bacteria that use the second Box 1. The zipper and trigger models

The zipper mechanism Listeria ( Figure Ia, top) , Neisseria and Yersinia are examples of bacteria that enter using the zipper mechanism. These bacteria express proteins on their surfaces that interact with cellular receptors, initiating signalling cascades that result in close apposition of the cellular membrane around the entering bacteria (Figure 1a , bottom). Actin polymerization and modest membrane extensions finally lead to bacterial internalization. For example, the listerial protein InlB interacts with Met, promoting Met auto-phosphorylation, the recruitment of the protein adaptors Gab1, Cbl and Shc and activation phosphatidylinositol 3-kinase (PI 3-kinase) and the small GTPase Rac, which in turn promotes actin polymerization through the actin-binding Arp2/3 and Wave complexes. This interaction of InlB with Met also promotes ubiquitination of the receptor and the recruitment of the clathrin-dependent endocytic machinery, including clathrin and dynamin, to the bacterial entry site. Finally, bacteria are endocytosed in a clathrin-coated vesicle. It is possible that actin polymerization is also associated with the endocytic machinery in an Arp2/3-independent manner, as it has been shown that the actinbinding protein cortactin and CD2AP are important for Listeria internalization.

The trigger mechanism Shigella (Figure Ib, top) and Salmonella are the best-studied examples of bacteria entering cells using the trigger mechanism. These bacteria bypass the necessity to bind to a cellular receptor and use type III secretion systems to inject protein effectors that interact with the actin cytoskeleton. Type III secretion systems are complex protein machineries that enable the secretion of bacterial effectors directly from the bacterial cytoplasm into the cellular cytosol. The injected bacterial effectors promote massive actin polymerization and formation of macropinocytic membrane extensions loosely attached to the bacteria, and which eventually lead to bacterial internalization. For example, the Shigella protein IpaC triggers actin polymerization directly or in a manner dependent on the small GTPases Cdc42 and Rac. The Shigella effector VirA, which binds to tubulin heterooligomers and inhibits microtubule formation, can indirectly promote actin polymerization. Shigella infection also promotes the activation of the kinases Abl and Arg and phosphorylation of the adaptor protein Crk, which can activate Cdc42 and Rac in a process similar to that observed in filopodia formation. Another Shigella effector, IpgD, hydrolyzes phosphatidylinositol (4,5)bisphosphate (PIP2) to phosphatidylinositol (5) phosphate (PIP) and disconnects cortical actin from the membrane [74] . mechanism of entry, the trigger mechanism. Bacteria in this group actively inject effectors into the host cytoplasm using a specialized secretory apparatus, the type III secretion system. Some of these bacterial effectors modulate the actin cytoskeleton, producing massive polymerization of actin and membrane ruffling. This results in the formation of pseudopods loosely attached to bacteria, that enable bacterial internalization in a process similar to macropinocytosis [15, 16] . The two entry pathways share a requirement for actin polymerization.

For many years, drugs that interfere with the actin cytoskeleton (e. g. cytochalasin D) have been used as tools to distinguish between clathrin-dependent endocytosis and phagocytosis. It was generally thought that clathrinmediated endocytosis was actin-independent (see, for example, Ref. [17] ). As bacteria require the participation of the actin cytoskeleton to enter into host cells [15, 16] , and as the size of the vesicle harbouring a bacterium far exceeds the maximal size expected for a clathrin-coated vesicle, the hypothesis was that bacteria enter into non-phagocytic cells by phagocytic-like mechanisms. However, receptors used by zippering bacteria to enter into cells (e.g. Met, E-cadherin and integrins) can be endocytosed by a clathrin-dependent mechanism, and an increasing number of articles start to point to the necessary role of actin cytoskeleton in clathrinmediated endocytosis [3, 18, 19] . The requirement of the actin cytoskeleton was therefore not incompatible with the participation of clathrin-dependent endocytosis in bacterial entry. Challenging the dogma, it has been shown that Listeria invade non-epithelial cells by hijacking the clathrin-dependent endocytic machinery. There are also data implicating clathrin-mediated uptake for several other bacteria. Here, we discuss the possible role of clathrinmediated endocytosis in bacterial entry.

A shift in paradigm, the Listeria model Listeria monocytogenes is a Gram-positive bacterium responsible for listeriosis, a severe human infection with an overall 30% mortality rate. The clinical features include severe gastroenteritis, mother-to-child infections and central nervous system infections. L. monocytogenes can cross the intestinal, blood-brain and placental barriers. L monocytogenes is a facultative intracellular pathogen and can invade and replicate in epithelial cells and macrophages [15, 20] . As mentioned earlier, two bacterial proteins involved in entry have been described: InlA, which interacts with E-cadherin on epithelial cells, and InlB, a surface protein that enables L. monocytogenes to enter into most non-phagocytic cells by interaction with its cellular receptor Met. Met belongs to the receptor tyrosine kinase (RTK) family and is involved in diverse cellular functions, such as scattering, invasion, proliferation, morphogenesis and angiogenesis. It is also implicated in a large number of human tumours, correlating closely with metastasis and poor prognosis [21, 22] . These tumorigenic activities occur when Met is overexpressed or when Met signalling after ligand (HGF) binding is not down-regulated [23] . The normal way used by cells to stop signalling downstream of Met and other RTKs is the ligand-dependent endocytosis and subsequent degradation of the activated receptor [21, 23] .

Interaction of Met with soluble InlB results in the clathrin-dependent endocytosis of Met [24, 25] . As observed by immunofluorescence, clathrin and dynamin, the major proteins involved in clathrin-dependent endocytosis [1] , localize at bacterial entry sites (Figure 1 and see the supplementary material online) [25] . Cbl, the ubiquitin ligase responsible for ubiquitination and subsequent endocytosis of Met and other growth factors [26] [27] [28] [29] , also localizes at bacterial entry sites [25] . The possible role in bacterial entry of the major proteins involved in the clathrin-dependent endocytosis of growth factor receptors, including clathrin heavy chain, dynamin and Cbl, was tested by small interfering RNA (siRNA), which resulted in great reduction in bacterial entry [25] . Moreover, the relevance of other components of the endocytic machinery, such as growth factor receptor-binding protein (Grb2), epidermal growth factor pathway substrate 15 (eps15), Cbl-interacting protein of 85 kDa (CIN85) and CD2 associated protein (CD2AP), all of which are proteins necessary for ligand-induced endocytosis of receptor tyrosine kinases [2, 19, 30, 31] during bacterial entry was shown by siRNA knock-down. Decreased expression of these proteins strongly inhibited L. monocytogenes entry [25] , demonstrating a major role of the clathrin-dependent endocytic machinery during L. monocytogenes infections.

Bacteria might therefore use the clathrin-dependent endocytosis machinery to enter non-phagocytic cells, challenging established ideas about the maximum size permitted for a clathrin-coated vesicle. Note that Listeria is a bacillus reaching 2-6 mm in length.

Several other pathogenic bacteria entering by the zipper mechanism recognize membrane receptors that are susceptible to being endocytosed. A possible role of clathrin in the entry of such bacteria had been suggested, reinforcing the data obtained with Listeria and leading to the conclusion that a role for clathrin-dependent endocytosis in bacterial entry is probably the rule rather than the exception.

Yersinia pseudotuberculosis, a Gram-negative enteroinvasive bacterium, enters nonphagocytic cells by the interaction between a bacterial surface protein called invasin and host b1-integrins [32] . Expressing the inv gene (encoding invasin) confers to non-pathogenic Escherichia coli (E. coli inv + ) the ability to enter into non-phagocytic cells, mimicking the entry of Y. pseudotuberculosis [33] . Electron microscopy (EM) studies show that invasion of epithelial cells by E. coli inv + occurs through electron dense structures resembling clathrin-coated vesicles [34] . In addition, potassium depletion, which has been shown to inhibit clathrinmediated endocytosis [35] , also inhibits bacterial entry [34] . Moreover, microinjection into host cells of antibodies against clathrin or AP2 (the major clathrin adaptor in the plasma membrane [36] ) also inhibits bacterial entry [34] . Together, these results point to a role for the endocytosis machinery in Yersinia invasion.

Rickettsiae are obligate intracellular Gram-negative bacteria with a life cycle that includes an arthropod vector and mammalian hosts. The ubiquitous protein Ku70 has been recently identified as a cellular receptor used by Rickettsia conorii to infect mammalian host epithelial cells [37] . In the same study, the ubiquitin ligase Cbl was shown to localize with R. conorii during entry. Knocking down Cbl by siRNA inhibits bacterial internalization, suggesting a role for clathrin-dependent endocytosis in R. conorii invasion similar to that observed in L. monocytogenes.

Data coming from studies using drugs inhibiting endocytosis and microscopy studies also suggest a possible role of clathrin-dependent endocytosis in the entry of E. coli [38] [39] [40] [41] , Staphylococcus aureus [42, 43] , Streptococcus pneumoniae [44, 45] , Streptococcus dysgalactiae [46] , Ehrlichia risticii [17, 47] , Brucella abortus [48] , Klebsiella pneumoniae [49] , Legionella pneumophila [50] , Campylobacter jejuni [51] and Citrobacter freundii [51] . More controversial is the role of clathrin-dependent endocytosis in Neisseria and Chlamydia invasion.

Neisseria gonorrhoeae, the etiologic agent of the sexually transmitted disease gonorrhoea, can infect epithelial cells by binding to the asialoglycoprotein receptor (ASGPR) [52] . Endocytosis of ASGPR is clathrin-dependent and bacteria localize with clathrin and ASGPR during entry. In addition, monodansylcadaverine, which inhibits clathrin-dependent endocytosis, inhibits bacterial entry in such cells [53] . However, other studies show that treatment of epithelial cells with monodansylcadaverine had very weak or no effect on N. gonorrhoeae entry, and no clathrin was observed in the N. gonorrhoeae entry sites [54] .

Chlamydiae are Gram-negative obligate intracellular bacteria involved in a wide spectrum of human and other vertebrate diseases. EM studies show that Chlamydia psittaci and Chlamydia trachomatis enter epithelial cells using clathrin-coated pits [55] [56] [57] . In these studies, the infective forms of Chlamydia, called elementary bodies, were observed at coated pits and coated vesicles, and anticlathrin immunostaining indicated the presence of clathrin at the bacterial entry sites [56] . However, EM studies of Chlamydia invasion failed to find clathrin-coated pits associated with entry of the bacterium, and monodansylcadaverine had no effect on invasion [58] . Moreover, in cells expressing mutants of dynamin (dynamin I K44A) and of Eps15 (Eps15 D95-295) [59] , which inhibit clathrin-dependent endocytosis [60, 61] , the entry of C. trachomatis remained unaffected [59] , suggesting a clathrin-independent entry. These conflicting reports on the role of clathrindependent endocytosis suggest that Neisseria and Chlamydia could use different and alternative entry pathways; some of these could be clathrin-dependent and some not, probably depending on the receptor engaged.

Taken together, these data indicate that bacteria can use clathrin-dependent endocytosis as a mechanism to enter host cells. Thus, endocytosis clearly supports entry of particles larger than 1 mm, an observation that has broad implications for cell biology, immunology and infectious disease processes. The fact that clathrin can enable the entry of large vesicles was supported by EM studies of viral 502 Review TRENDS in Cell Biology Vol. 16 No.10 infections of epithelial cells, showing viral particles (VSV, influenza, parvovirus) in clathrin-coated pits or vesicles larger that 120 nm [62] [63] [64] .

The role of clathrin in the internalization of large particles was also pointed out many years ago in studies of latex bead internalization in macrophages using the deep-etch replica technique [65, 66] . These studies clearly showed clathrin lattices surrounding phagocytosed beads ( Figure 2) . However, the role of clathrin-mediated endocytosis in phagocytosis has remained controversial, and no role for clathrin was found in the phagocytosis of immu-noglobulinG-coated particles larger than 3 mm [67] .

Our view on endocytosis is continuously changing, and further studies of pathogen-host interactions will probably contribute to a better understanding of how cells communicate with their environment. Bacteria, or beads coated with ligands of cellular receptors, could be used as tools to understand the basic mechanisms of endocytosis. As bacteria or coated beads are larger than soluble macromolecules, they can be detected easily and the proteins involved can be spatially and temporally followed.

Given that the interactions between bacterial proteins with their cellular receptors are highly specific, the presence of the receptors determines which cell types and species are susceptible to a given pathogen. The efficiency of invasion processes, as well as the exact mechanism of uptake used by each bacterium, depends mainly on the specific receptor engaged, which is unknown for the majority of pathogens. The shape of the pathogen could also have a role in bacterial endocytosis, as has been shown during phagocytosis [68] .

In agreement with results showing that the time required to complete the assembly of the endocytic complex is proportional to the size of cargo molecules [69] , Listeria using the InlB-Met pathway or InlB-coated beads take 4 min to enter epithelial cells (our unpublished results), which is longer than the endocytosis of macromolecules. It is thus possible that other bacteria that are far larger than macromolecules also take more time to enter into host cells. This prolonged internalization time, versus a transient signal, could affect the signalling and trafficking of the internalized particle.

The key issue that remains unsolved is the architecture of clathrin around entering bacteria. It is known that in endosomes there are zones of flat or irregular clathrin [70] [71] [72] . Thus, it could be possible that clathrin assembles as flat layers at the entry sites of bacteria and then cover the invaginating membrane, as previously shown for entering beads (Figure 2 ) [65] . This point deserves further investigation.

Supplementary videos associated with this article can be found online at doi:10.1016/j.tcb.2006.08.005. Review TRENDS in Cell Biology Vol. 16 No.10 

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