John M. Leong

Multiple β1 chain integrins are receptors for invasin, a protein that promotes bacterial penetration into mammalian cells

Abstract Mammalian cell receptors that promote entry of intracellular bacteria into nonphagocytic cells have not been identified. We show here that multiple members of the integrin superfamily of cell adhesion receptors bind the Y. pseudotuberculosis invasin protein prior to bacterial penetration into mammalian cells. Affinity chromatography of crude detergent extracts demonstrated that integrins containing the subunit structures α 3 β 1 , α 4 β 1 , α 5 β 1 , and α 6 β 1 bound to immobilized invasin. Furthermore, phospholipid vesicles containing isolated integrin proteins were able to attach to invasin. Specificity for invasin binding to the identified integrin receptors was also demonstrated, as immunoprobing and phospholipid reconstitution studies showed that the α 2 β 1 integrin, β 2 chain integrins, and vitronectin receptor ( α v β 3 ) were not involved in cellular attachment to invasin.

Identification of the integrin binding domain of the Yersinia pseudotuberculosis invasin protein.

The invasin protein of the pathogenic Yersinia pseudotuberculosis mediates entry of the bacterium into cultured mammalian cells by binding several beta 1 chain integrins. In this study, we identified the region of invasin responsible for cell recognition. Thirty‐two monoclonal antibodies directed against invasin were isolated, and of those, six blocked cell attachment to invasin. These six antibodies recognized epitopes within the last 192 amino acids of invasin. Deletion mutants of invasin and maltose‐binding protein (MBP)‐‐invasin fusion proteins were generated and tested for cell attachment. All of the invasin derivatives that carried the carboxyl‐terminal 192 amino acids retained cell binding activity. One carboxyl‐terminal invasin fragment and seven MBP‐‐invasin fusion proteins were purified. The purified derivatives that retained binding activity inhibited bacterial entry into cultured mammalian cells. These results indicated that the carboxyl‐terminal 192 amino acids of invasin contains the integrin‐binding domain, even though this region does not contain the tripeptide sequence Arg‐Gly‐Asp.

Hierarchical Regulation of WASP/WAVE Proteins

Members of the Wiskott-Aldrich syndrome protein (WASP) family control actin dynamics in eukaryotic cells by stimulating the actin nucleating activity of the Arp2/3 complex. The prevailing paradigm for WASP regulation invokes allosteric relief of autoinhibition by diverse upstream activators. Here we demonstrate an additional level of regulation that is superimposed upon allostery: dimerization increases the affinity of active WASP species for Arp2/3 complex by up to 180-fold, greatly enhancing actin assembly by this system. This finding explains a large and apparently disparate set of observations under a common mechanistic framework. These include WASP activation by the bacterial effector EspFu and a large number of SH3 domain proteins, the effects on WASP of membrane localization/clustering and assembly into large complexes, and cooperativity between different family members. Allostery and dimerization act in hierarchical fashion, enabling WASP/WAVE proteins to integrate different classes of inputs to produce a wide range of cellular actin responses.

Tails of two Tirs: actin pedestal formation by enteropathogenic E. coli and enterohemorrhagic E. coli O157:H7

Enteropathogenic Escherichia coli (EPEC) and enterohemorrhagic E. coli O157:H7 (EHEC) form characteristic lesions on infected mammalian cells called actin pedestals. Each of these two pathogens injects its own translocated intimin receptor (Tir) molecule into the plasma membranes of host cells. Interaction of translocated Tir with the bacterial outer membrane protein intimin is required to trigger the assembly of actin into focused pedestals beneath bound bacteria. Despite similarities between the Tir molecules and the host components that associate with pedestals, recent work indicates that EPEC and EHEC Tir are not functionally interchangeable. For EPEC, Tir-mediated binding of Nck, a host adaptor protein implicated in actin signaling, is both necessary and sufficient to initiate actin assembly. In contrast, for EHEC, pedestals are formed independently of Nck, and require translocation of bacterial factors in addition to Tir to trigger actin signaling.

A tyrosine‐phosphorylated 12‐amino‐acid sequence of enteropathogenic Escherichia coli Tir binds the host adaptor protein Nck and is required for Nck localization to actin pedestals

Enteropathogenic Escherichia coli (EPEC) and enterohaemorrhagic E. coli (EHEC) each promote the reorganization of actin into filamentous pedestal structures beneath attached bacteria during colonization of the intestinal epithelium. Central to this process is the translocation of the protein Tir (translocated intimin receptor) into the plasma membrane of host cells, where it interacts with the bacterial outer membrane protein intimin and triggers cellular signalling events that lead to actin rearrangement. Actin signalling by EPEC Tir requires a tyrosine residue, Y474, which is phosphorylated in the host cell. In contrast, EHEC Tir lacks this residue and generates pedestals independently of tyrosine phosphorylation. Consistent with this difference, recent work indicates that EHEC Tir cannot functionally replace EPEC Tir. To identify the role that tyrosine phosphorylation of EPEC Tir plays in actin signalling, we generated chimeric EHEC/EPEC Tir proteins and identified a 12‐residue sequence of EPEC Tir containing Y474 that confers actin‐signalling capabilities to EHEC Tir when the chimera is expressed in EPEC. Nck, a mammalian adaptor protein that has been implicated in the initiation of actin signalling, binds to this sequence in a Y474 phosphorylation‐dependent manner and is recruited to the pedestals of EPEC, but not of EHEC.

The Resolution of Relapsing Fever Borreliosis Requires IgM and Is Concurrent with Expansion of B1b Lymphocytes

The rate of pathogen clearance is a critical determinant of morbidity and mortality. We sought to characterize the immune response responsible for the remarkably rapid clearance of individual episodes of bacteremia caused by the relapsing fever bacterium, Borrelia hermsii. SCID or Rag−/− mice were incapable of resolving B. hermsii infection, indicating a critical role for T and/or B cells. TCR−/− mice, which lack T cells, and IL-7−/− mice, which are deficient in both T cells and follicular B cells, but not in B1 cells and splenic marginal zone (MZ) B cells, efficiently cleared B. hermsii. These findings suggested that B1 cells and/or MZ B cells, two B cell subsets that are known to participate in rapid, T-independent responses, might be involved. The efficient resolution of the episodes of moderate level bacteremia by splenectomized mice suggested that MZ B cells do not play the primary role in clearance of this bacterium. In contrast, xid mice, which are deficient in B1 cells, suffered more severe episodes of bacteremia than wild-type mice. The hypothesis that B1 cells are critical for clearance of B. hermsii was further supported by a selective expansion of the B1b (i.e., IgMhigh, IgD−/low, Mac1+ CD23−, and CD5−) cell subset in infected xid mice, which coincided with the eventual resolution of infection. Finally, mice selectively incapable of secreting IgM, the dominant isotype produced by B1 cells, were completely unable to clear B. hermsii. Together these results support the model that B1b cells generate the T-independent IgM required for the control and resolution of relapsing fever borreliosis.

Identification of a candidate glycosaminoglycan‐binding adhesin of the Lyme disease spirochete Borrelia burgdorferi

Binding of glycosaminoglycans (GAGs) by Borrelia burgdorferi, the Lyme disease spirochete, has the potential to promote the colonization of diverse tissues. GAG binding by B. burgdorferi is associated with haemagglutination and we have identified a 26 kDa protein, which we have termed Bgp (BorreliaGAG‐binding protein), on the basis of its ability to bind to heparin and erythrocytes. Bgp was found in outer membrane fractions of B. burgdorferi and on the surface of intact bacteria, as assayed by labelling with a membrane‐impermeable biotinylating agent or anti‐Bgp antibodies. Purified recombinant Bgp agglutinated erythrocytes, binds to the same spectrum of GAGs as the B. burgdorferi strain from which the cloned bgp sequence was obtained, and inhibited B. burgdorferi binding to purified GAGs and to cultured mammalian cells. Thus, Bgp is a strong candidate for a GAG‐binding adhesin of B. burgdorferi.

Role for the outer membrane ferric siderophore receptor PupB in signal transduction across the bacterial cell envelope

The outer membrane protein PupB of Pseudomonas putida WCS358 facilitates transport of iron complexed to the siderophores pseudobactin BN8 and pseudobactin BN7 into the cell. Its synthesis is induced by the presence of these specific siderophores under iron limitation. The signal transduction pathway regulating siderophore‐dependent expression of pupB was shown to consist of two regulatory proteins, PupI and PupR, and the PupB receptor itself. Mutational analysis of the regulatory genes suggested that PupI acts as a positive regulator of pupB transcription, whereas PupR modifies PupI activity dependent on the presence of pseudobactin BN8. PupI and PupR do not share homology with the classical bacterial two‐component systems but display significant similarity to the FecI and FecR proteins of Escherichia coli involved in regulation of ferric dicitrate transport. The function of the PupB receptor in pupB regulation was studied by the use of chimeric receptor proteins composed of PupB and the ferric pseudobactin 358 receptor PupA. This experiment revealed that PupB is involved in the initiation of the signal transduction pathway, implying a so far unique role for an outer membrane protein in signal transduction.

Fibronectin Binding Protein BBK32 of the Lyme Disease Spirochete Promotes Bacterial Attachment to Glycosaminoglycans

ABSTRACT Borrelia burgdorferi, the agent of Lyme disease, causes a multisystemic illness that can affect the skin, heart, joints, and nervous system and is capable of attachment to diverse cell types. Among the host components recognized by this spirochete are fibronectin and glycosaminoglycans (GAGs). Three surface-localized GAG-binding bacterial ligands, Bgp, DbpA, and DbpB, have been previously identified, but recent studies suggested that at least one additional GAG-binding ligand is expressed on the spirochetal surface when the spirochete is adapted to the mammalian host environment. BBK32 is a surface lipoprotein that is produced during infection and that has been shown to bind to fibronectin. In this study, we show that, when BBK32 was produced from a shuttle vector in an otherwise nonadherent high-passage B. burgdorferi strain, the protein localized on the bacterial surface and conferred attachment to fibronectin and to mammalian cell monolayers. In addition, the high-passage strain producing BBK32 bound to purified preparations of the GAGs dermatan sulfate and heparin, as well as to these GAGs on the surfaces of cultured mammalian cells. Recombinant BBK32 recognized purified heparin, indicating that the bacterial attachment to GAGs was due to direct binding by BBK32. This GAG-binding activity of BBK32 is apparently independent of fibronectin recognition, because exogenous heparin had no effect on BBK32-mediated bacterial binding to fibronectin.

Characterization of a candidate Borrelia burgdorferi beta3-chain integrin ligand identified using a phage display library.

The spirochaetal agents of Lyme disease, Borrelia burgdorferi (sensu lato) bind to integrins αIIbβ3, αvβ3 and α5β1 in purified form and on the surfaces of human cells. Using a phage display library of B. burgdorferi (sensu stricto) DNA, a candidate ligand for β3‐chain integrins was identified. The native B. burgdorferi protein, termed p66, is known to be recognized by human Lyme disease patient sera and to be expressed on the surface of the spirochaete. We show here that recombinant p66 binds specifically to β3‐chain integrins and inhibits attachment of intact B. burgdorferi to the same integrins. When expressed on the surface of Escherichia coli, this protein increases the attachment of E. coli to a transfected cell line that expresses αvβ3, but not to the parental cell line, which expresses no β3‐chain integrins. Localization of p66 on the surface of B. burgdorferi, the ability of recombinant forms of the protein to bind to β3‐chain integrins and the fact that p66 and B. burgdorferi bind to β3‐chain integrins in a mutually exclusive manner make p66 an attractive candidate bacterial ligand for integrins αIIbβ3 and αvβ3.